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Findings from a longitudinal study of farmer decision influencers for Best Management Practices,
Queensland, AustraliaRachel Hay and Lynne Eagle
Final Report
Findings from a longitudinal study of farmer
decision influencers for Best Management Practices,
Queensland, Australia
Rachel Hay & Lynne Eagle
College of Business Law and Governance, James Cook University
Supported by the Australian Government’s
National Environmental Science Program
Project 2.1.3 Harnessing the science of social marketing and behaviour change
for improved water quality in the Great Barrier Reef: An Action Research Project
© James Cook University, 2019
Creative Commons Attribution
Findings from a longitudinal study of farmer decision influencers for Best Management Practices, Queensland,
Australia is licensed by James Cook University for use under a Creative Commons Attribution 4.0 Australia licence.
For licence conditions see: https://creativecommons.org/licenses/by/4.0/
National Library of Australia Cataloguing-in-Publication entry:
978-1-925514-44-5
This report should be cited as:
Hay, R., & Eagle, L., (2019) Findings from a longitudinal study of farmer decision influencers for Best Management
Practices, Queensland, Australia. Report to the National Environmental Science Program. Reef and Rainforest
Research Centre Limited, Cairns (209 pp.).
Published by the Reef and Rainforest Research Centre on behalf of the Australian Government’s National
Environmental Science Program (NESP) Tropical Water Quality (TWQ) Hub.
The Tropical Water Quality Hub is part of the Australian Government’s National Environmental Science Program
and is administered by the Reef and Rainforest Research Centre Limited (RRRC). The NESP TWQ Hub addresses
water quality and coastal management in the World Heritage listed Great Barrier Reef, its catchments and other
tropical waters, through the generation and transfer of world-class research and shared knowledge.
This publication is copyright. The Copyright Act 1968 permits fair dealing for study, research, information or
educational purposes subject to inclusion of a sufficient acknowledgement of the source.
The views and opinions expressed in this publication are those of the authors and do not necessarily reflect those
of the Australian Government.
While reasonable effort has been made to ensure that the contents of this publication are factually correct, the
Commonwealth does not accept responsibility for the accuracy or completeness of the contents, and shall not be
liable for any loss or damage that may be occasioned directly or indirectly through the use of, or reliance on, the
contents of this publication.
Cover photographs: Lynne Eagle
This report is available for download from the NESP Tropical Water Quality Hub website:
http://www.nesptropical.edu.au
i
CONTENTS
Contents .................................................................................................................................. i
List of Tables ......................................................................................................................... iv
List of Figures ...................................................................................................................... viii
Acronyms .............................................................................................................................. ix
Abbreviations ........................................................................................................................ ix
Acknowledgements ................................................................................................................ x
Executive Summary .............................................................................................................. 1
Introduction ................................................................................................................. 3
1.1 Overall project objectives and anticipated outcomes ............................................... 4
1.2 Report Structure ...................................................................................................... 4
Literature Review: Key Findings ................................................................................ 5
2.1 Initial Literature Review ........................................................................................... 5
2.2 Additional Literature since the Original Review ........................................................ 6
Confounding Factors .................................................................................................. 8
3.1 Water Quality Improvement Programmes ................................................................ 8
3.2 Mass Media and Digital Media ................................................................................ 8
3.3 Directions for Further Research .............................................................................10
Critical evaluation of marketing strategies used for Reef Programme and the Reef Trust
Tender ..................................................................................................................................12
Methodology ..............................................................................................................14
5.1 Survey ....................................................................................................................14
5.2 Measurement Instrument .......................................................................................14
5.2.1 Survey Methodology Limitations ...........................................................................15
5.3 Structural Equation Modelling .................................................................................15
5.3.1 Structural Equation Modelling ...............................................................................15
5.3.2 Fertilizer application behaviour .............................................................................16
5.3.3 Run-off practices ..................................................................................................16
5.3.4 Attitudes, perceived norms and perceived behavioural control .............................16
5.3.5 Motivations towards behaviour .............................................................................16
5.3.6 Limitations of SEM relevant to the research..........................................................17
Results ......................................................................................................................19
6.1 First Round (2016/17) Data Summary of Findings ..................................................19
6.1.1 Burdekin and Wet Tropics Sugar Cane, Results from Round 1 Land Managers
Survey ...........................................................................................................................19
ii
6.1.2 Round 1 Structural Equation Model Results .........................................................21
6.1.3 Recommendations................................................................................................28
6.1.4 Limitations ............................................................................................................28
6.2 Second Round (2017) Data Summary of Findings: Wet Tropics and Burdekin .......28
6.2.1 Wet Tropics Comparison between Extension Officers and Cane Growers Decision
Making Influencers and Nutrient Management Practices ...............................................28
6.2.2 Recommendations................................................................................................31
6.2.3 Limitations ............................................................................................................31
6.3 Third Round (2018) Data Summary of Findings: Comparison between first round
(2016/17) and third round (2018) Data ..............................................................................31
6.3.1 Wet Tropics Sugar Cane Nutrient and Run-off Management Practices, Results from
Round 3 Land Managers Survey ...................................................................................31
6.3.2 Burdekin Sugar Cane Nutrient and Run-off Management Practices, Results from
Round 3 Land Managers Survey ...................................................................................54
6.3.3 Burdekin Grazing Nutrient and Run-off Management Practices, Results from Round
3 Land Managers Survey ..............................................................................................82
6.3.4 Round 3 Data Structural Equation Modelling Results ......................................... 107
6.3.5 Recommendations.............................................................................................. 114
6.3.6 Limitations .......................................................................................................... 114
Response to Research Objectives ........................................................................... 115
7.1 Research Objective 1 ........................................................................................... 115
7.2 Research Objectives 2 & 5 ................................................................................... 116
7.3 Research Objectives 3 & 4 ................................................................................... 119
7.4 Research Objective 5 ........................................................................................... 120
7.5 Research Objective 6 ........................................................................................... 122
Recommendations and Conclusion.......................................................................... 124
8.1 Recommendations ............................................................................................... 124
8.2 Recommendations Based on the Literature Review (Eagle et al., 2016b) ............ 124
8.3 Recommendations Based on the Documentary Analysis of Marketing
Communications Material and subsequent Communications Best Practice Guide (Hay &
Eagle, 2016b, 2019) ....................................................................................................... 124
8.4 Recommendations Based on First Round Descriptive Data Analysis Wet Tropics and
the Burdekin (Farr et al., 2017b, 2017c; Farr et al., 2017d) ............................................. 125
8.5 Recommendations Based on Second Round Data: Views from Extension Officers
(Hay & Eagle, 2018) ....................................................................................................... 127
8.6 Recommendations Based on Third Round Data. Final Report: Findings from a
longitudinal study of farmer decision influencers for Best Management Practices (Hay &
Eagle, 2019) ................................................................................................................... 131
iii
8.7 Recommendations based on Data Collection and Analysis .................................. 132
8.8 Conclusion ........................................................................................................... 132
References ......................................................................................................................... 136
Appendix 1: Overview of SEM and Summary of Measurement Items ................................. 143
Appendix 2: Independent Samples t-test (section 5.3.1) .................................................... 149
Appendix 3: Examples of innovative Nutrient Management practices, anecdotal comments
from Wet Tropic Sugar Cane land managers, coded .......................................................... 151
Appendix 4: Examples of innovative Nutrient Management practices, anecdotal comments
from DRy Tropics Sugar Cane land managers, coded ........................................................ 157
Appendix 5: Examples of innovative Run-off Management practices, anecdotal comments
from Burdekin grazing land managers, coded .................................................................... 159
Appendix 6: Top Causes of poor water quality in local streams, rivers and waterways,
anecdotal comments from Wet Tropics land managers, coded ........................................... 161
Appendix 7: Top pressures on the health of the Great Barrier REef, anecdotal comments from
Wet Tropics land managers, coded .................................................................................... 171
Appendix 8: Top Causes of poor water quality in local streams, rivers and waterways,
anecdotal comments from Burdekin land managers (Cane), coded .................................... 181
Appendix 9: Top pressures on the health of the Great Barrier REef, anecdotal comments from
Burdekin land managers (Cane), coded ............................................................................. 184
Appendix 10: Top Causes of poor water quality in local streams, rivers and waterways,
anecdotal comments from Burdekin Grazing land managers, coded .................................. 188
Appendix 11: Top pressures on the health of the Great Barrier REef, anecdotal comments from
Burdekin Grazing land managers, coded ............................................................................ 195
Appendix 12: Feedback from land manager survey, impact of urban development on water
quality ................................................................................................................................. 204
Appendix 13: Project Outputs ............................................................................................ 207
iv
LIST OF TABLES
Table 1: Media activity regarding the health of the Great Barrier Reef theme of article by
time period ...................................................................................................... 9
Table 2: SEM Indirect Effects of Fertilizer application behaviour through ‘Least time
consuming’ ....................................................................................................22
Table 3: Indirect Effects of Handling Run-off Practices through ‘least time consuming’ ..
......................................................................................................................25
Table 4: Indirect Effects of Handling Run-off Practices through ‘reduce business risk’ 26
Table 5: Wet Tropics land managers personal goals to achieve on farm/property .......32
Table 6: Wet Tropics land manager responses decision making drivers ......................34
Table 7: Wet Tropics participant responses to the question 'How do you calculate
fertiliser application rates?" ............................................................................35
Table 8: Wet Tropics land manager responses to 'How do you calculate fertiliser
application rates? - Other' ..............................................................................36
Table 9: Cross tabulation of Wet Tropics land managers ‘Advice land managers follow
most when calculating fertiliser rates’ and ‘how do you calculate fertiliser
application rates - my advisor does this for me’ .............................................36
Table 10: Advice followed most when calculating fertiliser rates - *Other. Who? ...........37
Table 11: Advice Wet Tropics land managers follow when calculating fertiliser rates,
ranked 1 most important to 12 least important – 1st Round Data Collection ...38
Table 12: Advice Wet Tropics land managers follow when calculating fertiliser rates,
ranked 1 most important to 12 least important – 3rd Round Data Collection ...39
Table 13: Wet Tropics land manager attitudes and motivations associated with calculating
fertiliser application rates ...............................................................................40
Table 14: Compared to other ways of calculating fertiliser rates, what motivates Wet
Tropics land managers to use the system that they use?...............................41
Table 15: Comparison between 'How first and third round Wet Tropics land managers
calculate fertiliser application rates’ ...............................................................42
Table 16: Wet Tropics land manager responses to the question 'how do you handle run-
off from rainfall or irrigation?’ .........................................................................43
Table 17: Advice Wet Tropics land managers follow when handling run-off, ranked 1 most
important to 12 least important – 1st Round Data Collection ..........................44
Table 18: Advice Wet Tropics land managers follow when handling run-off, ranked 1 most
important to 12 least important – 3rd Round Data Collection ..........................45
Table 19: Wet Tropics land manager attitudes and motivations associated with handling
run-off ............................................................................................................46
Table 20: Compared to other ways of handling run-off, what motivates Wet Tropics land
managers to use the system that they use? ...................................................46
Table 21: Comparison between 'How first and third round Wet Tropics land managers
handle run-off’ ................................................................................................47
Table 22: Other innovative practices - anecdotal comments from Wet Tropics land
managers, coded (see Appendix 3 for examples) .........................................48
Table 23: Means analysis of the statement about how nutrient loss impacts Wet Tropics
water quality ..................................................................................................48
Table 24: Wet Tropics land managers - Top causes of poor water quality in local streams,
rivers and water ways ....................................................................................50
v
Table 25: Means analysis of Wet Tropics land manager statement about the role cane
growing plays in the declining health of the Great Barrier Reef ......................50
Table 26: Wet Tropics land manager - two top pressures on the health of the Great Barrier
Reef ...............................................................................................................52
Table 27: Burdekin sugar cane land manager’s personal goals to achieve on
farm/property .................................................................................................55
Table 28: Burdekin sugar cane land manager responses decision making drivers ........57
Table 29: Type of irrigation tools used by Burdekin sugar cane land managers ............59
Table 30: Advice Burdekin sugar cane land managers follow when considering irrigation,
ranked 1 most important to 12 least important – 3rd Round data collection – top
5 ....................................................................................................................60
Table 31: Burdekin sugar cane land manager attitudes and motivations associated with
scheduling irrigation .......................................................................................61
Table 32: Compared to other ways of scheduling irrigation, what motivates Burdekin sugar
cane land managers to use the system that you use? ...................................62
Table 33: Comparison between 'How first and third round Burdekin sugar cane land
managers manage irrigation’ .........................................................................63
Table 34: Burdekin sugar cane land manager responses to the question 'How do you
calculate fertiliser application rates?" .............................................................64
Table 35: Advice sugar cane land managers from the Burdekin follow when calculating
fertiliser rates, ranked 1 most important to 12 least important – 1st Round data
collection .......................................................................................................65
Table 36: Advice sugar cane land managers from the Burdekin follow when calculating
fertiliser rates, ranked 1 most important to 12 least important – 3rd Round data
collection .......................................................................................................66
Table 37: Burdekin sugar cane land manager attitudes and motivations associated with
calculating fertiliser application rates .............................................................67
Table 38: Compared to other ways of calculating fertiliser rates, what motivates Burdekin
sugar cane land managers to use the system that they use? .........................67
Table 39: Burdekin sugar cane land manager comparison between 'How first and third
round land managers calculate fertiliser application rates’ .............................68
Table 40: Burdekin sugar cane land manager responses to the question 'how do you
handle run-off from rainfall or irrigation?’ ........................................................69
Table 41: Advice Burdekin sugar cane land managers follow when handling run-off,
ranked 1 most important to 12 least important – 1st Round Data Collection ..70
Table 42: Advice Burdekin sugar cane land managers follow when handling run-off,
ranked 1 most important to 12 least important – 3rd Round Data Collection ..71
Table 43: Burdekin sugar cane land manager attitudes and motivations associated with
calculating fertiliser application rates .............................................................72
Table 44: Compared to other ways of handling run-off, what motivates sugar cane land
managers in the Burdekin to use the system that you use? ...........................72
Table 45: Comparison between 'How first and third round Burdekin sugar cane land
managers handle run-off from rainfall or irrigation’ .........................................74
Table 46: Other innovative practices used by Burdekin sugar cane land managers -
anecdotal comments coded (see Appendix 4 for examples) ..........................75
Table 47: Means analysis of Burdekin sugar cane land managers to the statement about
how nutrient loss impacts water quality from the Burdekin region ..................75
vi
Table 48: Two top causes of poor water quality in local streams, rivers and water ways –
Burdekin ........................................................................................................77
Table 49: Means analysis of Burdekin sugar cane land manager statement about the role
cane growing plays in the declining health of the Great Barrier Reef .............77
Table 50: Burdekin - two top pressures on the health of the Great Barrier Reef ............79
Table 51: Burdekin grazing land managers personal goals to achieve on farm/property82
Table 52: Burdekin sugar cane land manager responses decision making drivers ........85
Table 53: Proportion of paddocks that were spelled by Burdekin Grazing Land Managers
in the most recent Wet Season ......................................................................86
Table 54: Anecdotal comments about what Burdekin grazing land managers plan to do
differently when spelling paddocks next year .................................................86
Table 55: Anecdotal Responses from Burdekin Graziers about how they spell their
paddocks .......................................................................................................87
Table 56: Advice Burdekin grazing land managers follow when making decisions about
paddock spelling, ranked 1 most important to 13 least important – 1st Round
Data Collection ..............................................................................................88
Table 57: Advice Burdekin grazing land managers follow when making decisions about
paddock spelling, ranked 1 most important to 13 least important – 3rd Round
Data Collection ..............................................................................................89
Table 58: Burdekin grazier land manager attitudes and motivations associated with
pasture spelling practices ..............................................................................90
Table 59: Compared to other ways of managing pasture spelling, what motivates Burdekin
grazier land managers to use the system that they use? ...............................91
Table 60: Burdekin grazier intentions for adjusting stock rates to paddock conditions
(other than wet season spelling) ....................................................................92
Table 61: Advice Burdekin grazing land managers follow when making decisions about
stocking rates, ranked 1 most important to 13 least important – 1st Round Data
Collection .......................................................................................................93
Table 62: Advice Burdekin grazing land managers follow when making decisions about
stocking rates, ranked 1 most important to 13 least important – 3rd Round Data
Collection .......................................................................................................93
Table 63: Burdekin grazier land manager attitudes and motivations associated with
adjusting stocking rates .................................................................................94
Table 64: Anecdotal comments from Burdekin land managers about who/what is forcing
them to adjust stocking rates .........................................................................95
Table 65: Compared to other ways of adjusting stocking rates, what motivates Burdekin
grazier land managers to use the system that they use? ...............................95
Table 66: Burdekin land manager’s practices for managing stock around waterways ....97
Table 67: Anecdotal comments from Burdekin grazing land managers about other
practices they are using to manage stock around waterways ........................98
Table 68: Advice Burdekin grazing land managers follow when making decisions about
managing stock around waterways, ranked 1 most important to 13 least
important – 1st Round Data Collection...........................................................99
Table 69: Advice Burdekin grazing land managers follow when making decisions about
managing stock around waterways, ranked 1 most important to 13 least
important – 3rd Round Data Collection ..........................................................99
Table 70: Burdekin grazier land manager attitudes and motivations associated with stock
management around waterways .................................................................. 100
vii
Table 71: Anecdotal comments from Burdekin grazing land managers about who/what is
forcing them to manage stock around waterways ........................................ 101
Table 72: Compared to other ways of managing stock around waterways, what motivates
Burdekin grazier land managers to use the system that they use? ...................
.................................................................................................................... 101
Table 73: Other innovative practices - anecdotal comments from Wet Tropics land
managers, coded (see Appendix 5 for examples) ........................................ 102
Table 74: Means analysis of Burdekin grazing land managers to the statement about how
soil loss impacts water quality from the Burdekin region .............................. 103
Table 75: Burdekin grazing land managers two top causes of poor water quality in local
streams, rivers and water ways – Burdekin .................................................. 103
Table 76: Means analysis of Burdekin grazing land manager statement about the role
cane growing plays in the declining health of the Great Barrier Reef ........... 104
Table 77: Burdekin grazing land managers - two top pressures on the health of the Great
Barrier Reef ................................................................................................. 105
Table 78: Estimates of Water Quality Behaviours ........................................................ 108
Table 79: Relationship of Goals and TPB Constructs .................................................. 109
Table 80: Factors activated when making decisions about what to do on the land
managers farm or property .......................................................................... 116
viii
LIST OF FIGURES
Figure 1: Estimated Model of Fertilizer Application Behaviour, Wet Tropics and Burdekin
......................................................................................................................23
Figure 2: Estimated Model of Run-off Handling Practices, Wet Tropics ........................27
Figure 3: Responses from Wet Tropics land managers about nutrient loss from their
property impacting local streams, rivers and waterways ................................49
Figure 4: Responses from Wet Tropics land managers about the role cane growing plays
in the declining health of the Great Barrier Reef ............................................51
Figure 5: Responses from Burdekin sugar cane land managers about nutrient loss from
their property impacting local streams, rivers and waterways ........................76
Figure 6: Responses from Burdekin sugar cane land managers about the role cane
growing plays in the declining health of the Great Barrier Reef ......................78
Figure 7: Responses from Burdekin grazing land managers about the role grazing
industry plays in the declining health of the Great Barrier Reef .................... 104
Figure 8: Run-off Behaviour - Cane Growers, Burdekin .............................................. 110
Figure 9: Run-off Behaviour - Cane Growers, Wet Tropics ......................................... 111
Figure 10: Fertilizer Application Behaviour - Cane Growers, Burdekin .......................... 112
Figure 11: Fertilizer Application Behaviour: Cane Growers, Wet Tropics ..................... 113
Figure 12: Social Network of a North Queensland Cane Farmer .................................. 128
Figure 13: Farmer Typologies and Learning Preferences ............................................. 130
Figure 14: Simple statistical model with one mediator .................................................. 144
Figure 15: An example for simplified multilevel linear SEM based on the TPB .............. 145
ix
ACRONYMS
BMP .............. Best Management Practice
CBSM ............ Community Base Social Marketing
DAF ............... Department of Agriculture and Fisheries
DES ............... Department of Environment and Science
DoEE ............ Department of the Environment and Energy
GBR .............. Great Barrier Reef
NESP ............ National Environmental Science Programme
NQ ................ North Queensland
NQDT ............ NQ Dry Tropics
NRM .............. Natural Resource Management
RRRC ............ Reef and Rainforest Research Centre Limited
SMOG ........... “Simple Measure of Gobbledegook” Readability Measurement
SNA ............... Social Network Analysis
TPB ............... Theory of Planned Behaviour
TWQ .............. Tropical Water Quality
WQ ................ Water Quality
ABBREVIATIONS
β ................... Beta
4Ps ................ Commercial Marketing’s Product, Price, Place and Promotion
HA ................. Hectares
M ................... mean
ML ................. Mega Litres
SD ................. Standard Deviation
p .................... Probability
λ .................... Lambda
x
ACKNOWLEDGEMENTS
This project, supported through funding from the Australian Government’s National
Environmental Science Program (NESP) Tropical Water Quality (TWQ) Hub, would not have
been possible without the kind support and help of many individuals and organisations.
We sincerely acknowledge contributions towards the project from the Department of the
Environment and Energy (DoEE), Reef Trust, Department of Environment and Science (DES)
and the Department of Agriculture and Fisheries (DAF). We would also like to acknowledge
contributions towards the project and the kind cooperation and encouragement from staff at
NQ Dry Tropics, Terrain Natural Resource Management, the Wet Tropics Sugar Industry
Partnership, the Great Barrier Reef Marine Park Authority, and the sugar cane industry working
groups.
Our thanks and appreciation goes to our colleagues in developing the project and others who
have willingly helped throughout the project, especially Muhammad Abid Saleem for his
contribution to the structural equation modelling and associated dialogue.
1
EXECUTIVE SUMMARY
This is the final report for this project – Harnessing the science of social marketing and
behaviour change for improved water quality in the GBR: An action research project. It
provides an analysis and comparison of data collected from land managers in the Burdekin
(two data collection points) and Wet Tropics (WT) (three data collection points) regions. It also
provides a number of specific recommendations for key stakeholders regarding possible
actions that should be considered in future interactions with land managers. Individual area-
specific reports have already been provided to each of the two Natural Resource Management
(NRM) organisations in whose regions the data was collected. We note that there were
considerable problems with the data collection in both regions, leading to both considerable
delays in obtaining the data and lower than ideal response rates and only two rather than the
planned three sets of data from the Burdekin region. This has resulted in the analysis of some
parts of the data sets being restricted to descriptive statistics. A more detailed discussion of
the specific problems faced is provided in the methodology section.
This project aimed to generate information to inform the design of marketing and engagement
strategies associated with water quality (WQ) improvement strategies so that they better
‘match’ the motivations, values and other social characteristics of land managers in the GBR.
The findings aim to improve uptake/adoption of WQ improvement programmes with greater
associated changes in behaviour and thus greater returns on investment. This project sought
to identify the barriers to, and potential enablers of behaviour change in relation to agricultural
run-off and to thus encourage BMP uptake amongst land managers who have not previously
engaged, either fully or partially in BMP-related activity.
Working in partnership with staff from the Australian Government’s Department of the
Environment and Energy (DoEE), and the Queensland Government’s Department of
Environment and Science (DES), this project used data collected from land managers and
elsewhere to critically evaluate the way WQ improvement programmes are ‘marketed’.
Insights from those evaluations were used to inform the reconfiguration of marketing and
engagement strategies associated with programmes scheduled for roll-out during 2017.
The key barriers identified were:
• Conflicting information over time from the range of organisations active in this sector,
including changing advice from state and federal governments.
• Distrust of government agencies and resentment of what is perceived as unfair blaming
of land managers, coupled with denial on the part of some participants in the studies
that their activity is detrimental to the GBR.
• Treating all land managers as homogenous rather than tailoring communications to
better fit with personality types and level of commitment to best land management
practices.
• Resistance of some extension officers to change and refusal to engage in discussions
with those land managers who follow different land management practices to those
officially advocated.
• Uneven coverage of land manager properties by extension officers, with a
concentration on those who are engaged rather than trying to encourage higher levels
of engagement from those partially engaged or disengaged.
2
• Complexity of applications for, and perceived unfairness of, available grant / funding
initiatives.
Factors that may encourage uptake of BMP can be summarised as:
• Engagement of extension staff in discussions regarding the implications of the findings
presented in this and preceding reports report for their own practice. The discussion of
relevance of the findings detailed in this should be led by someone from within their
own community who has the necessary skills.
• Upskilling all personnel such as, but not restricted to, extension officers in the
application of theory and communication frameworks, especially the principles of social
marketing, to practice, the use of a range of social media platforms to communicate to
stakeholders, and the importance of visual imagery in reinforcing key messages. We
note, however, that some extension officers have shown themselves to be resistant to
change, while others feel that any form of innovation is discouraged by their
organisations. Where a culture of resisting change or discouraging innovation by
organisations exists, then this needs to be addressed by all delivery partners including
hosting industry organisations and NRMs.
• Ensuring all communication, by whatever means, sends consistent, integrated
messages irrespective of source, and channelling communication through trusted
sources.
• Develop systems for monitoring and analysing messages from a range of sources,
including the news media and fertiliser reseller and also strategies for minimising the
impact of competing and conflicting messages.
• Develop proactive relationships with both traditional and digital media organisations.
• Recognise the overall diversity of information sources and preferences among land
managers and tailor information strategies accordingly.
• Incorporate long-term relationship management strategies based on customer
relationship management and business to business marketing concepts.
• Develop specific strategies for reaching and engaging those who are less than fully
committed to adopting recommended best land management practices.
Note – further details regarding the main recommendations are provided in the
Recommendations section of this report.
This report should be read in conjunction with the range of reports previously provided,
especially the review of literature in the area and the reports for the related project 3.1.3 which
focussed on an analysis of the readability of existing material provided to land managers.
3
INTRODUCTION
Adoption of best practice land management (BMP) strategies to improve WQ has been low in
some regions and previous water quality programmes may have encouraged BMP only
amongst those land managers who were already pre-disposed to management practices. This
project sought to encourage BMP uptake amongst land managers who have not previously
engaged.
BMP reef-related programmes often assume that land managers are motivated by profit –
offering financial (dis)incentives or seeking to ‘prove’ that BMP will raise profits. Finances are
not the sole driver of on-farm conservation activities: socio-cultural and environmental values
are crucially important to land managers and residents. Even those who focus on money may
not focus on profit; they may instead wish to minimise cost, risk and/or maintain flexibility. This
may explain why financial payments for on-farm conservation initiatives do not always
generate ‘additionality’ (the effect or an intervention), and suggests that the incentives used to
encourage BMP are unlikely to appeal to all land managers. For a detailed discussion see
(Eagle, Hay, & Farr, 2016b)
Importantly, encouraging behaviour change is not simply about getting incentives ‘right’. A
vast body of literature focuses on behaviour, the ‘power of persuasion’ and the social
acceptance of new knowledge establishing that to change behaviour one must win a ‘battle of
ideas’ for a seminal paper, see Peattie & Peattie (2003). Programmes have an implicit or
explicit persuasive message embedded within (Eagle et al., 2016b). Messages can be ‘framed’
positively or negatively and communicated to target audiences through different mediums (e.g.
pamphlets, extension officers). No single mode of framing or communication works in all
situations due to a host of interacting factors, including: the intrinsic and extrinsic
motivators/incentives, value orientations, descriptive and injunctive social norms, social
networks and preferred communication channels of targeted groups; perceptions of
intervening barriers/enablers; whether new or existing behaviours are targeted; whether
personal freedoms are perceived to be threatened and those involved are ‘trusted; and the
functional literacy of targets. Different factors may drive the behaviour of different population
segments and in different social contexts, hence the need to develop context-specific
intervention strategies, see Hay & Eagle (2016a) and Hay, Eagle and Chan (2018) for further
discussion.
Consistent with a plea to determine “what works, for whom, in what circumstances and for how
long” (Marteau, Ogilvie, Roland, Suhrcke, & Kelly, 2011, p. 264), this project uses insights from
the science of social marketing and behaviour change to implement (and test the efficacy of)
changes to the marketing and engagement strategy associated with programmes designed to
be rolled out under the Reef 2050 Plan. It aimed to change key behaviours, particularly
amongst those who have not previously engaged, to improve WQ.
4
1.1 Overall project objectives and anticipated outcomes
The objectives that were set at the commencement of this project were:
Objective 1: Identify intrinsic and extrinsic motivations (motivations), value-orientations
(values), norms, ‘habits’ (particularly relating to NRM), social networks and communication
protocols of different segments of land managers (particularly graziers and cane growers)
in regions where WQ improvement programmes have recently been, or will soon be, rolled
out.
Objective 2: Assess reactions of land managers to complexities of language, message
framing and communication channels (‘messaging’) used in the programmes, perceptions
of barriers to and potential enablers of adoption of these programmes, perceptions of
‘threats’ to personal freedoms and ‘trust’ in the programme.
Objective 3: Examine similarities and differences in (1) and (2) between the land
managers who have (do), and have not (do not), chosen (choose) to participate in the
programmes.
Objective 4: Identify mismatches between the extrinsic incentives and marketing
messages of evaluated programmes and the motivations, values, norms, habits and
communication protocols of both participating and non-participating land managers.
Objective 5: Work with those who are implementing new programmes to use insights from
(1) – (4) above, to suggest and, where appropriate, implement ‘live’ alterations to
marketing and engagement strategies, i.e. undertake adaptive alterations to those
strategies to encourage participation amongst those likely to be disinclined to participate.
Objective 6: Assess the efficacy of these interventions, determining if they result in
changed behaviours that are likely to generate more significant improvements in WQ than
would otherwise occur.
The anticipated outcomes include:
• WQ improvement programmes that are designed (and marketed) in ways that better
match the motivations and values of land managers in the GBR.
• Greater uptake/adoption of WQ improvement programmes with greater associated
changes in behaviour; thus a greater return on investment.
• Insights about land managers and ways to tailor programmes to increase adoption that
are transferrable to other contexts.
• Insights into ways of measuring the ‘impact’ of interventions that are transferrable to
other contexts.
1.2 Report Structure
This report provides an update on developments across the project to date including a
summary of the literature review key findings in Section 2.0, confounding factors surrounding
the project in Section 3.0 and an outline of the methodology for data collection, analysis and
structural equation modelling in response to the project schedule in Section 5.3. Section 6.0
provides the results of each round of data collection over three years, 2016 (first round), 2017
(second round) and 2018 (third round). The discussion in Section 7.0 applies the findings as
a response to the research objectives and Section 8.8 concludes the project and makes
recommendations. This is the final report for this project.
5
LITERATURE REVIEW: KEY FINDINGS
2.1 Initial Literature Review
NESP TWQ Hub Project 2.1.3 Initial Report, (Eagle et al., 2016b)
The initial project literature review was intended to provide an extensive review of the existing
literature relating to behaviour change, either directly in the agri-environment context, or from
wider contexts where findings may then be applied to agri-environmental issues. A specific
focus was placed on the use of social marketing approaches, acknowledging the complex
range of influences on behaviours and pressures, such as climate change and extreme
weather events that are beyond the control of land managers.
The tensions between land managers perceived freedom to manage their land in the way they
believe will provide them with the best outcomes, and the range of attempts to influence that
behaviour have been well documented in previous studies and were summarised in the initial
report. There is a need to recognize the range, complexity and magnitude of barriers to
behaviour change together with the need to identify potential enablers of sustained behaviour
change.
The major behaviour change tools were reviewed, including the role of behavioural economics
and social marketing concepts, together with examples of successful social marketing- based
interventions. Two widely used social marketing approaches, Community-Based Social
Marketing and the National Social Marketing Centre’s Benchmarks were compared and
contrasted, with a view to synthesizing them for the agri-environment context. These should
be viewed in the context of a range of behavioural influences that are seldom explicitly
considered in intervention design. An intention to develop a synthesis of these approaches
was signalled in the initial report and recently published in the Journal of Marketing
Management (Rundle-Thiele et al., 2018).
As there is a considerable body of evidence regarding the value of using behaviour change
theories to help in the analysis of the relative importance of a range of behavioural influences,
a discussion of the way theory can be used to underpin future behavioural change interventions
is provided. These influences include the impact of conflicting or competing information and
the key role of social norms alongside attitudes and beliefs regarding abilities to undertake and
maintain behaviours.
The influence of limited literacy and numeracy abilities for a large percentage of the population
is under-recognised in behaviour change activity. Therefore, these factors are reviewed,
together with other cognitive limitations such as the ability to perceive environmental impacts
over a long period of time. Tools for evaluating the readability of printed material (including
Internet-based material) were noted in this report but covered in depth in a separate report
(Hay & Eagle, 2016a. Harnessing the science of social marketing and behaviour change for
improved water quality in the GBR: Documentary Analysis). This is followed by a review of
the impact of message framing and message tone factors and the use of visual imagery and
subsequent ‘Best Practice Guide’ (Hay et al., 2018. NESP TWQ Hub Project 3.1.3 Harnessing
the science of social marketing and behaviour change for improved water quality in the Great
6
Barrier Reef: Final report best practice guide for development and modification of program
communication material.).
As agri-environmental behaviour is strongly influenced by a complex range of social factors
such as peer approval, the importance of communities and social networks in accepting the
need to change and adapt behaviours, a discussion of the importance of the need to
understand the interplay of these factors was included. This was followed by a review of
collaborative approaches to behaviour change, including knowledge brokerage, social learning
and collaborative partnerships and co-management activity.
This review formed the foundation for the development of the research questions used in the
first round of data collection (see Farr, Eagle, & Hay, 2016).
2.2 Additional Literature since the Original Review
Recent additions to the academic literature include multiple papers relating to the health of the
Great Barrier Reef, but excluding specific marine science analyses of specific parts of the
ecosystem. Examples of recent literature relevant to this project include:
• Crown-of-thorns starfish outbreaks, with increasing recent citations of a paper (Miller
et al., 2015) suggesting that direct linkages of outbreaks to increased levels of nutrients
such as fertilizer in water may have been overstated.
• Coral bleaching causes and effects (see, for example, Wolanski, Andutta,
Deleersnijder, Li, & Thomas, 2017). Coverage of the back-to-back bleaching events
and recent cyclones have also led to acknowledgement that the GBR is “under
pressure from a suite of stressors” (Wolff, Mumby, Devlin, & Anthony, 2018, p. 1978)
• Impact of mining, with one paper suggesting the recently approved Adani mine will be
a “public health disaster” (McCall, 2017, p. 588). We also note significantly increased
media coverage of this issue (see Section 3.2)
• Concerns about the lack of an integrated catchment-wide management structure (see,
for example, Dale et al., 2017) and criticisms of both the complexity of legislative and
regulatory systems together with ‘political ideology’ that are seen as a barrier to more
effective adaptive management practices (Tan & Humphries, 2018). There is also a
global call for ecosystem management structures “that better balance conservation
objectives and stakeholder interests” (Weijerman et al., 2018, p. 1823).
• Concerns regarding the limited success of water quality improvement programmes (De
Valck & Rolfe, 2018) and the need for cooperation between management agencies
(Day, 2018).
Two factors stressed in the original literature review have received recent focus: The first
highlights the need to consider both the economic and social influences on sugar cane farmers’
run-off management (Deane et al., 2018, p. 691). The need for transparency, accountability,
equity and fairness are highlighted as necessary for effective practice change. The second
related to the need for trust in natural resource management communication (MacKeracher,
Diedrich, Gurney, & Marshall, 2018, p. 29). Deane et al., (2018) also stresses that the provision
of information alone is insufficient to change behaviours.
7
While there are very few human-factor focussed agri-environment papers, there is a growing
focus on extension workers and their challenges, particularly in developing countries,
especially in Africa (Bachewe, Berhane, Minten, & Taffesse, 2018; Cafer & Rikoon, 2018;
Shitu, Shitu, Nain, & Singh). The small amount of material relevant to the Australian context
offers some interesting potential for development, including extension support services via
digital platforms (Mushtaq et al., 2017) and privatised extension services (Paschen, Reichelt,
King, Ayre, & Nettle, 2017).
8
CONFOUNDING FACTORS
3.1 Water Quality Improvement Programmes
Water quality improvement programmes in the Great Barrier Reef regions are primarily funded
by the Australian and Queensland Government with the primary objective to reduce sediment,
fertiliser and pesticide run-off into the GBR Basin. Confounding factors include multi-
organisation involvement in research in the GBR catchment area.
During the NESP TWQ Hub research (2015-2021) there have been a number of ‘competing’,
and, at times, ‘conflicting’, activity that is underway in both the Wet Tropics and Burdekin
regions. For example:
• “Cane Changer” (Canegrowers) John Pickering – includes similar questions to those
already used in the first round of 2.1.3).
• “Landscape Resilience” (NQ Dry Tropics, Lisa Pulman).
• “Project Catalyst” (Reef Catchments, Terrain, NQ Dry Tropics, Australian Government
– involves commercial partners such as Coca-Cola, WWF and Bayer).
• Announcements re additional funding via Reef Trust Phase IV Repeated Tenders –
See press release Terrain 19 June re $4.7 million in funding. Similar statements ex
NQ Dry Tropics.
• Grazing Best Management Extension Support
• SmartcaneBMP
• “Project NEMO”
• Sandy Creek (Pioneer River Floodplain – Mirani: inland from Mackay)
• “Connecting cane farmers to local wetlands” (NQ Dry Tropics, Laura Dunstan)
• Major Integrated Projects.
Therefore, the measurement of effects of any specific intervention are limited in that no one
programme’s success can be singularly measured within the regions.
3.2 Mass Media and Digital Media
We also note a significantly increased level of media activity regarding the health of the Great
Barrier Reef in 2017 compared to 2016, particularly as a result of two consecutive years of
coral bleaching and a number of conflicting reports regarding the extent and consequences of
this (for a review of the key themes within mass media in 2016, see Eagle, Hay, & Low, 2018).
This analysis was not part of the original project objectives but was undertaken to fill a gap in
knowledge regarding the impact of media activity. It is noted in the Recommendations section
that it would be beneficial to extend this analysis to incorporate 2018 and 2019 data and that
some form of ongoing tracking and analysis of media coverage should be implemented.
9
Table 1: Media activity regarding the health of the Great Barrier Reef theme of article by time period
Theme 2016 2017 Jan - June
2017 July- Dec
n % n % n %
Coral bleaching 59 24.4 161 21.7 41 3.0
Climate change / global warming / ocean acidification
34 14.0 156 21.1 126 9.2
Reef is dead / dying 25 10.3 41 5.5 11 0.8
Coal mining including Adani / dredging 25 10.3 87 11.7 194 14.1
Funding increase calls 20 8.3 7 0.9 0 0.0
UNESCO potential 'at risk' listing 19 7.9 4 0.5 19 1.4
Plastic bag ban 13 5.4 0 0.0 14 1.0
Shipping 12 5.0 15 2.0 22 1.6
Scientific disputes and controversy 11 4.5 5 0.7 11 0.8
Government actions including funding commitments
6 2.5 9 1.2 90 6.5
Water quality improvement 5 2.1 13 1.8 36 2.6
Reef Report card / Reef health reports 5 2.1 4 0.5 97 7.1
Cane monitoring compliance 4 1.7 0 0.0 0 0.0
Agriculture including Farmer protest negative portrayal
4 1.7 6 0.8 26 1.9
Solutions, Hope and Recovery 0 0.0 41 5.5 98 7.1
Sea Turtles 0 0.0 16 2.2 8 0.6
Travel Articles – encouraging visits to GBR 0 0.0 50 6.7 123 8.9
Advocacy, activism, Not-for-profit activity & Individual Actions
0 0.0 14 1.9 65 4.7
Cyclone Debbie & Whitsundays impact 0 0.0 34 4.6 12 0.9
Financial Costs and Impact on Tourism of bleaching etc. articles
0 0.0 12 1.6 43 3.1
Research: planned studies, laboratory experiments (e.g. coral cloning)
0 0.0 39 5.3 83 6.0
Deloitte Valuation of GBR 0 0.0 22 3.0 7 0.5
Chasing Coral 0 0.0 0 0.0 42 3.1
Crown of Thorns / Triton 0 0.0 0 0.0 25 1.8
Other: GBR mentioned only in context of wider unrelated content
0 0.0 5 0.7 182 13.2
Total 242 100 741 100 1375 100
The key themes emerging from the non-academic media in 2016 include:
• Global warming / ocean acidification / coral bleaching, including missed and conflicting
reports regarding bleaching versus recovery.
• Plastic pollution including, recently, concerns that corals are ingesting plastic debris
(Allen, 2017).
• Impact of mining, particularly the Adani mine and associated protests.
• Land clearing.
• Criticism of the draft 2050 water quality improvement plan.
Eagle et al. (2018) warned that the overwhelmingly negative tone of this coverage is likely to
erode public confidence in reef-related science. In addition, the authors warned of the possible
consequences of disagreement within the scientific community and its impact on the overall
credibility of science, particularly when no overt attempt is made to correct misconceptions.
Criticism of possible exaggeration of coral bleaching reports became evident in 2016 (see, for
example, Lloyd, 2016) and 2017, including impacts on tourist’s perceptions (Millard, 2017) as
well as on climate sceptic-supported sites (see, for example, Steele, 2017).
10
A detailed analysis of the 2017 media is currently in press and will be made available on
completion. However, the authors draw attention to the potential impact on stakeholders, such
as land managers, of persistent sensationalised and predominantly negative media coverage
of the GBR as this is likely to reinforce and strengthen perceptions that agriculture is being
unfairly blamed for water quality issues.
This is also reinforced by multiple documents and papers that acknowledge water quality
improvement targets are unlikely to be met, for example:
• “Queensland is likely to fail to achieve the reef water quality targets essential for
maintaining the health and resilience of the Great Barrier Reef” (Queensland
Government, 2017, p. 5)
• “On current trends transformational change in adoption rates will be needed to meet
various targets for water quality improvements” (Rolfe & Harvey, 2017, p. 277)
• “There is limited empirical evidence in the GBR of the water quality improvements likely
to result from changes in agricultural practices” (Thorburn & Wilkinson, 2013, p. 193)
• Even three decades ago there were concerns “We conclude that recent efforts in the
GBR catchments to reduce land-based pollution are unlikely to be sufficient to protect
the GBR ecosystems from declining water quality within the aspired time frames”
(Kroon, Thorburn, Schaffelke, & Whitten, 2016, p. 1985)
These authors continue their somewhat pessimistic analysis, stating that modelling suggests
that “even complete adoption of industry-supported BMPs for reducing sediment and nitrogen
discharges from the GBR catchments would not achieve water quality targets stipulated in
government policy”.
Given that the first round of data collection showed a high percentage of land managers did
not believe their practices had any effect on the health of the Great Barrier Reef, this coverage
is likely to reinforce and possibly even increase these perceptions.
3.3 Directions for Further Research
In order to fully understand the extent and nature of discussions regarding the health and future
of the GBR it is recommended that social media discussions, online video coverage and
documentaries of the GBR be contrasted with material from traditional media sources to
establish the effect of media on land managers beliefs about the effects of farming on the
health of the GBR, see Eagle, Hay and Low (2018).
There was a change of tone reflected in news media coverage between 2016 (242 articles)
and 2017 (741 articles). For example, in the first six months of 2017, the tone of articles in the
news media moved from mostly neutral (37.2%) to mostly negative or very negative (52%).
Similarly, while articles of hope and recovery increased slightly from 0% to 5.5%, they still do
not portray positive outcomes for the GBR. There are also new factors entering the news
media coverage themes e.g. algae and lower sea temperatures (Copp, 2017) and comments
regarding the imminent demise of the GBR are increasing, but also that the long term impacts
have yet to be evaluated. Given that the first round of data collection showed a high
11
percentage of land managers did not believe their practices had any effect on the health of the
Great Barrier Reef, this coverage is likely to reinforce and possibly even increase these
perceptions. Therefore, it is recommended that news media be contrasted and reported to
identify trends in the media, which may influence land managers opinions and behaviour.
Further research is required on the actual impact of tourism on different sections of the GBR
and an analysis of the impact of the tourism industry's strategies to mitigate the impact of
sensationalized reporting of likely future tourism experiences.
These analyses may then be used to inform a critical analysis of existing science
communication models to guide the development and testing of potential new models that may
be more applicable in the digital era.
12
CRITICAL EVALUATION OF MARKETING STRATEGIES
USED FOR REEF PROGRAMME AND THE REEF TRUST
TENDER
NESP TWQ Hub Project 3.1.3 Document Readability Analysis (Refer to Hay & Eagle, 2016
for full report)
The document readability analysis project critically evaluated programme marketing material
with the intention to assess the way that messages to land managers about water quality in
the Great Barrier Reef are presented in terms of their readability, message framing, and
message tone. Two programmes were selected (1) the Reef Programme (Wet Tropics and
Burdekin) and (2) the Reef Trust Tender (Burdekin). The programmes selected for evaluation
had been marketed within both the wet and the dry tropics, and they had been designed for
both graziers and cane farmers.
Overall, the readability analysis has shown all three programmes to be written at a similar level
well above the recommended reading level of grade / year 9 (Carbone & Zoellner, 2012; Kemp
& Eagle, 2008). The documents associated with the Reef Programme (Burdekin), with a
“Simple Measure of Gobbledegook” (SMOG) Readability Measurement score of 13, were
slightly more readable than documents associated with the Reef Trust Tender (Wet Tropics)
(SMOG score of 17) or the Reef Programme (Burdekin) (SMOG score of 18).
A readability score of 18 or above requires the reader to have achieved a university degree
and a score of 17 means that they must have received a level of further education beyond high
school, whereas for the readability level of 13 the reader must have at a minimum completed
and passed high school. Therefore, the analysis of water quality programme marketing
material indicates that many of the communications are written in language too complex for a
substantial percentage of the Australian population.
Each of the programmes analysed rated slightly different in terms of norms, tone and message
framing used. Most of the documents were written using positive and negative framing and
used both fear and guilt appeals. Some messages appeared to be collaborative and both
injunctive and descriptive norms were used to demonstrate approved methods of what land
managers ought to be doing and how other land managers were behaving. However, the
materials were largely dictatorial and sometimes patronising.
During the analysis, it became evident that there were limitations to the materials content
imposed by various Government Guidelines and the unavoidable use of three syllable words
such as government and management, which affected readability heavily.
Due to the nature of message communication, there are no standard rules to apply to norms,
message tone and framing. However, understanding the principles of communication can help
to deliver messages appropriate to the given audience see Hay et al., (2018).
The outcomes of the document readability analysis were used to inform stakeholders within
and beyond the regional natural resource management groups who supply the current
programmes to land managers. As a result, project managers from the wet and dry tropics
13
have implemented changes to their marketing communication material with positive results
(see Section 7.4).
Visual imagery was not a major focus on this project, but, given the importance of visuals in
effective communication noted in the academic literature, we recommend that additional
resources be targeted at examining this in a similar way to the readability analysis.
NESP TWQ Hub Project 3.1.3 Harnessing the science of social marketing in
communication materials development and behaviour change for improved water
quality in the GBR: Readability Desktop Review, drew on learnings from NESP
TWQ Hub Project 2.1.3 and from other past research to conduct a readability,
message tone and visual imagery analysis of communications material from a
selection of programme documents supplied by Australian and Queensland
Governments and other program managers as well as extension service
providers with the aim of increasing uptake of water quality improvement
programmes in the Great Barrier Reef Basin (see Section 7.4 Research Objective
5 for examples of how the results from NESP TWQ Hub Project 3.1.3 have been
incorporated into water quality programs).
14
METHODOLOGY
5.1 Survey
Surveys of land managers were undertaken in partnership with two of the six natural resource
management (NRM) organisations operating in areas adjacent to the GBR identified as having
a very high risk of natural and anthropogenic run-off (Brodie, Waterhouse, & Maynard, 2013).
NRM organisations, of which there are 56 in Australia, act under delegated authority from the
Federal Government to coordinate environmental management within their regions. The
sample population was obtained from a membership database within the Wet Tropics and
Burdekin regions. Participants include land managers from the both regions who engaged in
sugar cane production and cattle production. Quantitative and qualitative data were analysed
including open-ended responses.
The survey was developed using information gathered from an initial literature review related
to the science of social marketing (see Eagle et al., 2016b for more details) and from literature
surrounding agriculturally relevant behaviours that impact water quality (Churchill, 2017). The
need to alter approaches to behaviour change has been accepted by government agencies
including the need to determine “what works, for whom, in what circumstances and for how
long” (Marteau et al., 2011, p. 264).
Studies have shown “that behaviour change is more likely when more components of social
marketing are used” (Almestahiri, Rundle-Thiele, Parkinson, & Arli, 2017, p. 234). As with
other complex areas, Best Management Practice-focussed behaviour change activity lends
itself to a Social Marketing approach via an understanding of the influence of intrapersonal,
interpersonal, organisational, community and societal influences on behavioural decisions
across different segments of land managers. Social marketing is an approach that calls on a
variety of theoretical models. It is multidisciplinary and it provides a framework for developing
innovative solutions using a substantial research base to initiate change across communities,
organisations and society (Lefebvre, 2013). This approach is compatible with advocated
conservation marketing strategies (Bennett et al., 2017; Veríssimo, 2013; Wright et al., 2015).
5.2 Measurement Instrument
The questionnaire development included several rounds of feedback from stakeholders
including government and industry specialists, which resulted in an operational definition of the
Theory of Planned Behaviour (TPB) constructs. Use of a structured measurement instrument
in this study was justified from previous studies - it is a widely used approach of data collection
when the purpose is for testing the relationship of established theories (such as TPB in this
current study) (Field, 2017). Using the structured measurement instrument and survey
methods provides control over the data collection process, it is relatively easy to administer,
cost effective, and ultimately provides flexibility in subsequent data analysis (Bickman & Rog,
2009).
15
Data collection for the second round was continuously delayed in both NRM regions. Both
NRMs raised concerns about the data being shared with government departments and the
possibility of it [the data] being “used against us” [the NRMs]. In addition, NQDT were
investigating third party collection using industry partners to fulfil their contract as both the
quantity and quality of the Wet Tropics data (collected by the extension officers face-to-face),
was far better than the NQDT data that was collected via phone using graduate students.
Requests to make changes to the questionnaire by NQDT to suit the newly created MIP activity
were acknowledged and a small number of modifications to the questions were made as
requested. However, changes were not made to the detriment of the original objective of the
survey as this would have prevented any comparison being made between data collected at
different time periods and therefore prevent any measurement of behaviour change.
While Terrain NRM initially indicated that they would collect data via an online questionnaire
delivery, the method was changed whereby NRM extension officers completed their
questionnaire online, and administered the survey (including some common questions) face
to face with cane growers. This raises the issue of potential data contamination if extension
staff seek to align responses with their own responses see Section 6.2.3 Limitations. Second
round data collection commenced in the Wet Tropics region in late October 2017 (delayed from
the intended July 17 start date) with a shortened version of the questionnaires in order to focus
on a small number of behavioural areas. Concerns regarding a late change to the data
collection strategy within the Wet Tropics region were ratified, resulting in significant delays in
reporting for each round of data collection.
5.3 Structural Equation Modelling
Structural equation modelling (SEM) is a statistical procedure that uses data and qualitative
causality expectations for analysing and estimating causal relationships (Jahanshahi & Hall,
2013) between the variables (see Appendix 0 for an overview of SEM). SEM is a system of
equations and is a very powerful multivariate technique, which has been recognised as one of
the most suitable analytical tools to investigate and understand complex interrelated
relationships within the Theory of Planned Behaviour (Eagle, Hay, & Farr, 2016a; Gunzler,
Chen, Wu, & Zhang, 2013). The approach has been widely used in TPB-based studies mostly
in health (Adams & Boscarino, 2011; Bryan, Schmiege, & Broaddus, 2007; Vadaparampil,
Champion, Miller, Menon, & Skinner, 2004), travel (Bagley & Mokhtarian, 2002; Golob, 2003),
diving (Ong & Musa, 2012), and shopping (Hellier, Geursen, Carr, & Rickard, 2003; Homer &
Kahle, 1988). SEM allows the structural relationship between variables in the model to be
“modelled pictorially to enable a clearer conceptualization of the theory under study” (Brain,
2008, p. 3). “Relative weights of model constructs are determined empirically for the particular
behaviour and population under investigation. This information provides guidance as to which
constructs are most important to target for behaviour change effort” (Glanz, Rimer, &
Viswanath, 2008, p. 76). As such, the SEM has been chosen as the most appropriate approach
to analyse land managers’ behaviour in this project.
16
Farmers were engaged in six different types of fertilizer application behaviours (see Appendix
1 for a summary of measurement items). Feedback from stakeholders indicated that the
industry standard ‘six easy steps’ was the desired fertilizer application behaviour (Reef Water
Quality, 2016), therefore a binary approach was followed to operationalize fertilizer application
behaviour. The industry standard ‘SIX EASY STEPS’ was coded as ‘1’ (desired probable
behaviour) while all other practices were coded ‘0’.
Handling run-off practices was also conceptualised in the context of TPB, where farmers
adopted four different types of run-off practices. Insights from stakeholders indicated that using
‘recycle pits (Burdekin) or sediment traps (Wet Tropics)’ was the desired practice for handling
run-off. ‘Recycle pits/sediment traps’ practices were coded as ‘1’ (desired probable behaviour)
while all other practices were coded as ‘0’. We highlight that recycling pits are used in the
Burdekin, whereas sediment traps are only useful in the Wet Tropics if there is sufficient
sediment generated of a suitable grain size (>64um) and there is room and appropriate
landscape position to install one. The data is representative of those growers who indicate
that they were currently using sediment traps.
Farmers were advised to reflect on their attitude towards fertiliser application behaviour and
handling run-off practices where subjective norms, perceived behavioural control and
motivations towards behaviour were all conceptualised and measured in the same way, as
follows.
Attitudes towards fertilizer application behaviour were measured using a 4-items scale1. A
single item measured subjective norms while the perceived behavioural control construct was
measured by using a 3-items scale.
Four different sets of motivations guiding fertilizer application behaviour: lifestyle, financial or
economic goals, social goals and environmental goals were conceptualised (Farr, Eagle, Hay,
& Churchill, 2017b). Lifestyle, financial or economic goals, and social goals each were
measured by using 5-items scale, while a 6-items scale measured environmental goals.
Responses on all items were recorded on a 7-point Likert scale (1 ‘extremely unimportant’ to
7 ‘extremely important’).
1 Items scale – relates to a number of statements that are measured on a Likert scale, in this instance a 7-point Likert scale (1
‘extremely unimportant’ to 7 ‘extremely important’).
17
Although considerable care was exercised in design and execution of the project, there are
some theoretical as well as methodological gaps that need to be addressed in further
investigate water quality change behaviours. These gaps are related to how the TPB model is
developed and executed in this study.
As a tool to identify factors that play a major role in behaviour change using a social marketing
approach, the TPB requires a specific schematic conceptualization and organization of its
constructs considering the causal chain process proposed in its original form. Additionally, the
extended form of TPB requires to consider a more in depth analysis of how beliefs are formed
and affected by background factors. This belief-based approach of measurement is more
effective than direct measurement. Based on these additional considerations, the following
suggestions are provided:
• As the TPB was found to be the most appropriate to exploring factors explaining
farmers’ fertilizer application and run-off handling behaviours, the measurement of such
behaviours needs to be revisited. Fishbein and Ajzen (2010a) suggest that the actual
behaviour under study in the TPB proposal should be measured at a certain level of
specificity including reasonable time and a clear description of action.
• Further to revised measurement of actual behaviour, another important aspect of the
TPB proposal is that it follows a particular schematic arrangement of various constructs
to predict actual behaviour. Behavioural intention is considered as one of the most
important constructs in the TPB proposal that is considered as an immediate proxy of
actual behaviour. The reason why behavioural intention is often considered more
important than the actual behaviour is because the actual behaviour is contingent to
the availability of chances and choices, whereas, the behavioural intentions are free
from such controls. Even if the product availability or probability of behavioural
occurrence is not possible at a particular time, behavioural intentions are still the true
outcome of factors found to be affecting them. This is because behavioural intentions
represent present or future plans of action or choice which is not affected by certain
behavioural controls at any specific time. Nevertheless, this does not limit the prediction
of actual behaviour as the TPB proposal explicitly clarifies that the behavioural
intentions are tantamount to actual behaviour. Therefore, it is critical to examine
behavioural intentions prior to actual behaviour while the TPB proposal is implemented.
• As this project was limited to direct measurement and explanation of actual behaviour,
no relevant behavioural controls were defined or measured. In the actual TPB model,
behavioural intentions are translated into actual behaviours, subject to favourable
controls. Fertilizer application and Run-off handling behaviours are also a very complex
set of behaviours and need to be examined closely to identify if there are any factors
that might hinder (or facilitate) farmers intentions to actually convert into actual
behaviour.
• Another limitation of the TPB model utilized for fertilizer application and Run-off
handling behaviour in this project is the level and specificity of attitudinal measures that
lead to behavioural intention and consequently actual behaviour. While Fishbein and
Ajzen (2010b) advised that attitudinal constructs (subjective norms, attitude towards
behaviour and perceived behavioural control) should be measured at the same level of
specificity as the actual behaviour under study, this project could only utilize similar
18
measures of subjective norms, attitude towards behaviour and perceived behavioural
control. This needs to be revised as there are chances that the elements of subjective
norms, attitude towards behaviour and perceived behavioural control may differ for the
two different types of behaviours.
Finally, Fishbein and Ajzen (2010b) maintain that belief-based measures of subjective norms,
attitude towards behaviour, and perceived behavioural control are stronger than direct
measures of these constructs. They provide a value-expectancy-model to justify why belief
based measures are stronger than the direct measures. It is therefore suggested to reconfigure
the belief based measures of these constructs based on methods suggested by Fishbein and
Ajzen (2011).
19
RESULTS
A comparative evaluation of the effectiveness of water quality programs and their ability to alter
water quality related behaviours.
6.1 First Round (2016/17) Data Summary of Findings
Detailed reports were provided individually produced for the Burdekin (Farr, Eagle, Hay, &
Churchill, 2017d) and the Wet Tropics regions (Farr et al., 2017b) regions, followed by a report
comparing and contrasting the findings from the two regions (Farr et al., 2016). These reports
detailed the survey instrument development and sampling design. The reports provide a
preliminary descriptive statistical analysis of the initial data collected from land managers. They
also provide provisional recommendations for key stakeholders regarding possible actions that
should be considered in future interactions with land managers, these recommendations are
also presented in Section 8.4 of this report). An additional technical report was provided giving
detailed rationale for the research methodology and the selection of the TPB as a framework
for questions and the intended structural equation modelling analysis (Farr, Eagle, & Hay,
2017a)
Two questionnaires were developed for the initial round of data collection – one for cane
growers and one for graziers. When developing questionnaires, the aim was to keep questions
similar in each questionnaire wherever possible, to enable comparisons between both groups
(e.g. socio-demographics, attitudes and motivations) and between the case study areas (e.g.
cane growers in the Wet Tropics and cane growers in the Burdekin). Identical questions were
used to capture demographic information. The remaining questions were similar but made
specifically relevant to particular behaviours for the grazing and sugar cane industries. The
final versions of the questionnaire are included as Appendices in the reports noted above.
The preliminary analysis primarily captured land managers who were already engaged in
programs, including those that related to water quality improvement. Land managers who were
disengaged or only partially engaged with agri-environmental issues, were not included in this
sample.
Insights from the preliminary analysis of round one data showed that the respondents (n=134):
• Have a mature profile - the median age of cane growers in the Wet Tropics is 57 and
cane growers and graziers in the Burdekin is 52 years which is significantly greater
than the median age of the Australian population (37 years).
• Own or own and manage their property (65 per cent of cane growers in the Wet Tropics
and 80 per cent of cane growers and 84 per cent of graziers in the Burdekin).
• Have lengthy land management experience - (average of 29.2 years in the Wet Tropics,
18.9 years for graziers and 20.9 years for cane growers in the Burdekin), often following
earlier generations on properties: maintaining traditions and heritage is important (63%
20
of cane growers in the Wet Tropics and over 50% of respondents in the Burdekin
indicated this to be of the highest importance).
• Do not make decisions in isolation (43% of cane growers in the Wet Tropics and 41%
of cane growers and 66% of graziers in the Burdekin) – family / extended family are
commonly involved.
• Are positive about overall quality of life (>90% in both regions).
• Have no significant plans to change future practices (>90% in both regions).
• Do not believe their farming practice adversely impacts water quality in local streams,
rivers, and waterways (42% of cane growers in the Wet Tropics and 61% of cane
growers and 30% of graziers in the Burdekin).
• Do not believe that the cane/grazing industry plays a significant role in the declining
health of the Great Barrier Reef (GBR) (49% of cane growers in the Wet Tropics and
66% of cane growers and 39% of graziers in the Burdekin).
• Tend to shift the blame related to poor water quality and the poor health of the Great
Barrier Reef to other industries, organisations and individuals.
The first round of data collection made specific recommendations regarding the role of
extension officers:
“There is a potential to extend the key role of extension officers in potentially influencing
increased uptake of BMP practices. There is a need to recognise the key role of extension
officers and determine what professional development support might be beneficial in
continuing to build trust and engagement with land managers” (Farr et al., 2016, p. 63).
However, extension staff had discussed with the members of the research team that they were
not encouraged to have contact with disengaged land managers but rather to concentrate on
those already engaged. This is consistent with findings from other countries, for example the
USA where reluctance to try to build new relationships was evident, with the rationale that
expending resources on the disengaged could negatively impact on existing relationships with
those who are engaged and thus receptive to practice change (Diem, Hino, Martin, &
Meisenbach, 2011). This may also be due to short funding cycles and specific targets that
programs require resulting in the tendency for extension providers to focus on growers already
willing and engaged to ensure outcomes are met. One extension officer from this study noted
that they had been told not to visit farms run by members with a specific surname because
they were disengaged. However, when the research team investigated further, it appeared
that there are several unrelated families in the same region with the same surname, only one
of which is disengaged. This means that three other farms had not been visited by extension
officers. In addition, extension officers in the two surveyed regions have told the research
team that they are not encouraged to be innovative, new ideas are not encouraged by either
management or longer-serving fellow extension officers.
The round one data also highlighted that there is a high percent of land managers who do not
believe that their actions impact on the GBR, identifying a clear need to “sell the science”:
“There is a need to ‘sell the science’ to gain acceptance of the cause-effect
relationship between farming practice and water quality. NRM groups should
21
work with environmental science specialists to change views on the impact of
farming practice on water quality” (Farr et al., 2016, p. 56).
However in the initial literature review (Eagle et al., 2016b), we noted that there are problems
with the levels of trust in government-originated information, and thus also with “governments’
appraisal of causes and extent of ‘environmental problems” (Emtage & Herbohn, 2012, p. 358).
Note: The results of the Round 1 structural equation model is published with the Asia Pacific
Journal of Marketing and Logistics Information (March 2019). The journal article is entitled
“Social Marketing’s Role in Improving Water Quality on the Great Barrier Reef” (2019), see
Section 8.4.
The Theory of Planned Behaviour (TPB) informed questionnaire enabled structural equation
modelling to be undertaken with Round 1 data from the cane grower surveys (the Wet Tropics
and Burdekin regions) to measure the strength and nature of a range of possible behavioural
influences to explain current behaviours and, more importantly, to determine which of the
influences should be targeted in future interventions to enhance the likelihood of behaviour
change and where there are significant barriers that should be targeted to minimise their effect.
Grazier data will be included in structural equation modelling in the third round of data
collection.
Two types of behaviours were examined for cane growers: fertilizer application behaviour and
handling run-off practices. Fertilizer application and handling run-off practices behaviour in
GBR region strongly affects the water quality and consequently leads to changes in
biodiversity. The TPB was adapted to explain the factors influencing farmers’ cane growing
practices. TPB has been widely used in the literature and is reported to have strong
explanatory power for several behaviours in social, societal, environmental and
enviropreneurial marketing research (Ajzen, 1991, 2015; Bamberg & Schmidt, 2003;
Carrington, Neville, & Whitwell, 2010; Fishbein & Ajzen, 2010a). See Section 5.0 for an outline
of the methodology and Appendix 1 for a summary of the measurement items.
The findings indicate that the farmer’s choice of fertilizer application according to industry
standard was positively influenced by elements of life style and social goals through attitude
towards behaviour (see Table 2). Similarly, there was positive influence of environmental goals
on fertilizer application behaviour (following the industry standard) through subjective norms
(farmers I respect most do this). An interesting aspect in these findings is that some of the
factors influencing farmers to follow industry standards in fertilizer application failed to cast any
impact directly, for example ‘being able to make my own decisions’ (β1 = 0.052, p < 0.05),
‘sharing new ideas with others’ (β1 = 0.040, p < 0.05) and ‘having efforts recognised by the
larger community’ (β1 = 0.019, p < 0.05) had no effect on choice of fertiliser application.
However, when mediated by a positive attitude towards behaviour, their influence became
significant. This supports the conceptualisation that pro-social/ environmental behaviours can
be better understood in a theoretical framework rather than in isolation.
22
Table 2: SEM Indirect Effects of Fertilizer application behaviour through ‘Least time consuming’
Predictors (X) Consequent
Fertilizer Application
behaviour (Y)
Attitude towards behaviour ‘Least
time Consuming’ (M)
Indirect effect Confidence intervals Model Fit Status
Coefficient SE P Coefficient SE P Coefficient LL95%CI UL95%CI Negalkarke R2
Level of mediation
Lifestyle
Maintaining physical and mental health of family
0.153 0.077 0.048 0.302 0.113 0.007 0.046 0.002 0.128 0.0283 Partial mediation
Maintaining family traditions and heritage
0.151 0.077 0.05 0.209 0.073 0.004 0.031 0.0007 0.0904 0.0421 Partial mediation
Maintaining good relations with other farmers
0.131 0.137 0.923 0.289 0.110 0.009 0.047 0.0016 0.1353 0.0242 Full mediation
Social Goals
Being able to make own decisions
0.035 0.167 0.831 0.325 0.135 0.017 0.052 0.003 0.138 0.024 Full mediation
Sharing new ideas with others
0.129 0.117 0.268 0.271 0.092 0.003 0.040 0.002 0.113 0.031 Full mediation
Having efforts recognized by the larger community
0.026 0.075 0.723 0.154 0.077 0.047 0.019 0.0002 0.0634 0.023 Full mediation
23
Figure 5.1 provides an estimated model for fertilizer application behaviour in the Wet Tropics
and Burdekin regions. The dotted lines represent indirect relationships, * partial mediation, **
full mediation, Lifestyle 1: maintaining physical and mental health, Lifestyle 2: maintaining
family traditions and heritage, Lifestyle 3: maintaining good relations with others, Social Goals
1: being able to make own decisions, Social Goals 2: sharing new ideas with others, Social
Goals 3: having efforts recognized by larger community, Environmental Goals 1: maintaining
and improving water supplies and storage, Perceived Norms; farmers I respect do so.
Figure 1: Estimated Model of Fertilizer Application Behaviour, Wet Tropics and Burdekin
For practices related to handling run-off , the sample from the Wet Tropics was used because,
(a) the sample from the Burdekin was too small to estimate the model and (b) the combined
sample was not methodologically feasible to use. Differences in handling Run-off practices
exist among the farmers of Wet Tropics and the Burdekin (thus causing heterogeneity in the
sample characteristics).
The results found that for farmers in the Wet Tropics the practice of using recycle pits or
sediment traps for handling run-off was influenced by several motivational factors through
attitude towards behaviour (‘Least time consuming’ and ‘Best way to reduce business risk’)
(see Table 3 and Table 4)
Results show that attitude (i.e. least time consuming) negatively mediated the relationships of
lifestyle activities with handling run-off practices, including maintaining family traditions (β1 = -
0.142, p < 0.05), spending face-to-face time with family (β1 = -0.119, p < 0.05), keeping in
24
contact with family and friends (β1 = -0.109, p < 0.05) and maintaining good relations with
other farmers (β1 = -0.143, p < 0.05). Interestingly, two relationships ‘Spending face to face
time with family’ and ‘maintaining good relations with other farmers/graziers’, reflected full
mediation2 (see Table 3 and Table 4).The data is representative of those growers who indicate
that they were currently using sediment traps. Growers have identified lifestyle activities and
relationships as important to decision making, for example if a grower was to decide between
taking the family on an annual holiday (tradition) and implementing sediment traps then they
would choose a holiday because relationships are more important than sediment traps, so
decisions about using sediment traps may not only be about cost.
Financial motivations including low farm cost (β1 = -0.102, p < 0.05), maximization of profits
(β1 = -0.116, p < 0.05), minimizing risk (β1 = -0.105, p < 0.05) and servicing debt (β1 = -0.060,
p < 0.05) were found to have negatively mediating effects on run-off handling practices through
attitude (i.e. least time consuming). This may be because there is little cost benefit of using
sediment traps to growers in the Wet Tropics, unlike for growers in the Burdekin, who use
recycle pits to recycle water (and nutrients). Results also highlighted that social motivations
including time to pursue hobbies (β1 = -0.063, p < 0.05), being able to make own decisions
(β1 = -0.182, p < 0.05), learning about testing new ways of doing things (β1 = -0.082, p < 0.05),
sharing new ideas (β1 = -0.111, p < 0.05), and having efforts recognised by the wider
community (β1 = -0.047, p < 0.05) also have negatively mediated relationships through
attitude. All show full mediation except for ‘Having time to pursue hobbies’ (see Table 3).
One of the environmental goals, maintaining water supplies and storages (β1 = -0.043, p <
0.05), also had an impact on handling Run-off practices mediated negatively by attitudes. In
addition to the ‘Least time consuming’ attitude, the results showed that ‘Reduce business risk’
attitude also mediated several hypothesised relationships. Lifestyle, economic goals, and
environmental goals had an impact on run-off handling practices negatively mediated through
attitude ‘reduce business risk’ (see Table 5).
A focus on specific behaviours related to GBR water quality may help to bridge the gap
between those who do not believe their farming practices affects water quality and amongst
those who may be able to take individual or collective action. The complexity of factors that
affect land management practices means that no single policy instrument is likely to be
universally effective (Greiner, 2014; Rolfe & Gregg, 2015). Understanding the target’s lives,
behaviours and sources of information and influence, for example how and whom makes
decisions and both on and off farm behaviour may act as a conduit for pro-environmental
behaviour change.
2 Mediation seeks to identify and explain the mechanism or process that underlies an observed relationship between an independent variable and a dependent variable via the inclusion of a third hypothetical variable, known as a mediator variable. Full mediation would occur if inclusion of the mediation variable drops the relationship between the independent variable and dependent variable. Partial mediation maintains that the mediating variable accounts for some, but not all, of the relationship between the independent variable and dependent variable (Gunzler et al., 2013).
25
Table 3: Indirect Effects of Handling Run-off Practices through ‘least time consuming’
Predictors (X) Consequent
Run-off handling practices (Y)
Attitude towards behaviour ‘Least time
consuming’ (M)
Indirect effect
Confidence intervals Model Fit Status
Coefficient SE P Coefficient SE P Coefficient LL95%CI UL95%CI Negalkarke R2
Level of mediation
Lifestyle
Maintaining physical and mental health of family
0.022 0.186 0.906 252 0.241 0.299 -0.069 -0.245 0.024 0.064 NS
Maintaining family traditions and heritage
0.261 0.132 0.049 0.417 0.114 0.000 -0.145 -0.299 -0.048 0.092 Partial mediation
Spending face to face time with family
0.107 0.167 0.521 0.414 0.160 0.010 -0.119 -0.293 -0.023 0.067 Full mediation
Keeping in contact with family and friends
0.311 0.129 0.015 0.314 0.123 0.011 -0.109 -0.257 -0.019 0.106 Partial mediation
Maintaining good relations with other farmers/graziers
0.204 0.199 0.306 0.482 0.169 0.005 -0.143 -0.338 -0.035 0.071 Full mediation
Financial/economical goals
Keeping farm cost low 0.0167 0.169 0.921 0.370 0.160 0.021 -0.102 -0.266 -0.018 0.064 Full
mediation
Keeping a stable cash flow
0.094 0.187 0.614 0.264 0.220 0.231 -0.0743 -0.235 0.019 0.657 NS
Maximising farm profits -0.015 0.200 0.938 0.425 0.189 0.026 -0.116` -0.299 -0.019 0.064 Full
mediation
Minimizing risk of very high cost or very low income
-0.045 0.162 0.783 0.389 0.159 0.015 -0.105 -0.275 -0.019 0.064 Full mediation
Servicing debt 0.008 0.117 0.941 0.208 0.121 0.086 -0.060 -0.185 -0.003 0.071 Full
mediation
26
Table 4: Indirect Effects of Handling Run-off Practices through ‘reduce business risk’
Predictors (X) Consequent
Run-off handling practices (Y)
Attitude towards behaviour ‘Reduce business risk’ (M)
Indirect effect
Confidence intervals Model Fit Status
Coefficient SE P Coefficient SE P Coefficient LL95%CI UL95%CI Negalkarke R2
Level of mediation
Social goals
Having time to pursue hobbies
-0.244 0.114 0.034 0.266 0.087 0.002 -0.0627 -0.1571 -0.011 0.097 Partial mediation
Being able to make your own decisions
-0.345 0.262 0.188 0.777 0.142 0.000 -0.182 -0.411 -0.032 0.077 Full mediation
Learning about testing new ways
0.086 0.183 0.638 0.294 0.189 0.121 -0.082 -0.256 -0.0006 0.065 Full mediation
Sharing new ideas with others
-0.117 0.162 0.472 0.431 0.146 0.003 -0.111 -0.287 -0.026 0.067 Full mediation
Having efforts being recognised by the wider community
-0.0281 0.914 0.758 0.184 0.078 0.019 -0.047 -0.133 -0.008 0.058 Full mediation
Environmental goals
Maintaining water supplies and storages
0.038 0.097 0.694 0.173 0.078 0.027 -0.043 -0.119 -0.005 0.053 Full mediation
Lifestyle
Keeping in contact with
family and friends
0.2968 0.129 0.906 252 0.241 0.299 -0.069 -0.245 0.024 0.064 NS
Financial/economic goals
Servicing debt 0.025 0.118 0.921 0.370 0.160 0.021 -0.102 -0.266 -0.018 0.064 Full
mediation
Environmental goals
Leaving the farm in
better condition
0.335 0.250 0.034 0.266 0.087 0.002 -0.0627 -0.1571 -0.011 0.097 Partial
mediation
27
Figure 2 provides an estimated model of run-off handling practices in the Wet Tropics. The
dotted lines represent significant indirect relationships, Lifestyle 1: maintaining physical and
mental health, Lifestyle 2: maintaining family traditions and heritage, Lifestyle 3: maintaining
good relations with others, Lifestyle 4: keeping in contact with family and friends, Lifestyle 5:
maintaining good relations with other farmers, Social Goals 1: being able to make own
decisions, Social Goals 2: sharing new ideas with others, Social Goals 3: having efforts
recognized by larger community, Social Goals 4: having time to pursue hobbies, Social Goals
5: learning about testing new ways, Financial Goals 1: keeping farm cost low, Financial Goals
2: keeping a stable cash flow, Financial Goals 3: minimizing farm profits, Financial Goals 4:
minimizing risk of high cost, Financial Goals 5: servicing debt, Environmental Goals 1:
maintaining and improving water supplies and storage, Environmental Goals 2: leaving the
farm in better condition, Attitude towards Behaviour 1: least time consuming, Attitude towards
Behaviour 2: helps reduce business risk, Perceived Norms: farmers I respect do so.
Figure 2: Estimated Model of Run-off Handling Practices, Wet Tropics
28
A full list of recommendations from the first round of data collection can be found in Section
8.4.
See Section 5.3
6.2 Second Round (2017) Data Summary of Findings: Wet Tropics
and Burdekin
Round Two data collection in the Wet Tropics area was undertaken in late 2017 (delayed from
the intended July start date) with a shortened version of the questionnaires in order to focus
on a small number of behavioural areas. A comparison between land managers’ responses
and those of extension officers and others in contact with the land managers was made.
Extension officers and others were not formally surveyed during the first round data collection.
The inclusion of these personnel was at the request of the Wet Tropics region NRM body in
order to compare best practice perceptions and to determine whether there are substantial
differences in perceptions between land managers and extension and/or advisors.
Data collection strategies were also changed for the second round. The Wet Tropics region
initially agreed to collect data via an online questionnaire delivery for both land managers and
extension officers. This occurred for the extension officers but the land manager data was
then collected by the same extension officers through face to face interactions with the land
managers. Data was directly entered into iPads and downloaded to an on-line database.
The Burdekin region NRM initially advised that they were investigating third party collection as
both the quantity and quality of the first round of data in the Wet Tropics region (collected by
the extension officers face-to-face), was far better, both in quantity and the quality /
completeness of responses than the Burdekin region data that was collected via phone using
graduate students. Second round data collection was abandoned in the Burdekin region due
to a lack of time between the Round 2 and Round 3 data collection points. Instead data for
the Burdekin region was only collected twice - initially in 2016 (Round 1) and again in 2018
(Round 3), therefore the Burdekin region is not reported on in this section.
This section reports on the comparison of data from extension officers and cane growers in
the Wet Tropics region. The results are from the abridged version of the 2016 land manager
survey (see Farr et al., 2017b) that was delivered to extension officers in the Wet Tropics
region of Queensland, Australia in 2017 (Hay & Eagle, 2018). Due to the small sample size
the analysis is primarily descriptive and compares responses from extension officers in 2017
to responses from land managers in 2016.
29
The extension officers involved in the survey were from six of the nine catchment areas of the
Wet Tropics cane growing region (Hay & Eagle, 2018). The experience of extension officers
varies from 1-3 years to 35+ years in the industry. The insights from the analysis follow.
Decision Making Factors
The data identified that extension officers may be underestimating the importance of land
manager decision influencers, which may lead to distrust or lack of respect for the extension
officer. Misunderstanding the importance of decision influencers may change the way
messages are sent and received, which can significantly affect the way that messages about
water quality are processed and how they influence behaviour change (Hay & Eagle, 2018, p.
11).
Grants and Funding
How extension officers perceive success and or failure in grant applications (i.e. in 2016) may
present barriers or enablers for land managers who apply for grants or funding. If the land
manager perceives a threat of not receiving a grant or a very low chance of success, then the
land manager may not take the time to apply for any grants that are available and even if they
do apply, their application may be inhibited by its perceived slim chance of success i.e. they
may not put as much effort into the grant application if they perceive it is unlikely to be
successful (Hay & Eagle, 2018, p. 15). This may be influenced by the type of grant or funding
that the land manager applied for and the amount of obligation the extension officer has to
assisting the grower, i.e. whether the onus is on the grower alone to complete the grant
application or if it was a shared responsibility between grower and extension officer.
Workshops, Training Programs and Other Activities
Extension officers responded that land managers sought information about workshops, training
programs and other activities from their industry extension networks, industry bodies and
friends and personal networks. At the time of the survey, the workshops, training and activities
were important to improving land and soil management practices to raise awareness of water
quality issues as well as accreditation and networking. Extension officers thought that land
managers found all workshops useful, but in particular SIX EASY STEPS, soil health
workshops and SRA Masterclasses (offered to extension officers only) were identified as most
valuable. Extension officers indicated that holding workshops, training and other activities
outside of the harvest season, targeting skills deficiency and better coordinated systems would
make the activities work better for land managers. Extension officers responded that nutrient
management, soil chemistry, more involvement with extension officers and strategic
coordinated extension programs with assistance from the DEHP (now DES) would help in
future to assist land managers to make farm improvements (Hay & Eagle, 2018, p. 24)
highlighting that the “DEHP needs to be a presence to give the industry motivation to change”.
Nutrient Management Practices
There are some disparities between extension officers and land managers thoughts on how
land managers make decisions about nutrient management practices. When calculating
fertilizer application rates, land managers rated tailoring their own fertilizer rates higher than
using industry standards, while extension officers rated that they thought land managers used
the same responses but in reverse. Both land managers and extension officers identified that
land managers also use their advisors to calculate fertilizer application rates. Indicating with
some confidence that land managers are calculating fertilizer rates using industry standards.
30
However, extension officer’s anecdotal comments indicate that while land managers are using
the industry standard (SIX EASY STEPS), they are not necessarily following protocol and
hence may not be meeting the industry standard. Land managers indicated in anecdotal
comments that in addition to using best management practice they are also calculating fertilizer
rates based on experience, alternative methods, based on soil tests and by seeking advice
from local private agronomists. The majority of farmers are using these tools to calculate
fertilizer rates because their peers are also using these tools ( See Hay & Eagle, 2018, p. 27
for supporting data).
Drain Management Practices
In most cases extension officers indicated that land managers in the wet tropics do not capture
run-off from their farms. When they do capture run-off, they use grass headlands, drain
systems, laser levelling and sediment traps or recycle pits. Only 15.8% of extension officers
indicated that land managers use sediment traps, which is supported by anecdotal comments
that there is a limited use of sediment traps in the wet tropics region. Land managers are
influenced by other farmers when using the systems that they choose to handle run-off.
Extension officers are not sure if land managers in the wet tropics can afford to use the
practices available for handling run-off, but were confident that they had the technical
knowledge to do so. Extension officers and land managers nominated industry extension
advisors as people whose advice land mangers most frequently follow when handling run-off.
The least important advisors for capturing run-off identified by extension officers were regional
cane associations and Landcare (Hay & Eagle, 2018, p. 32).
Other Innovative Practices
Extension officers have identified land managers are using other innovative practices including
bed renovators, contour planting, experiments with flocculants (a particle clumping substance),
grassed headlands and riparian vegetation, wet land bioreactors (a natural water purification
process), sediment traps, minimum tillage, wetlands, spoon drains, subsurface fertilizer
application, headland management, well designed drainage, trash blanketing and spraying
out and covering fallowed fields. One extension officer stated that “the innovation is about
minimising the amount of sediment, DIN and chemicals, which is about placement, timing,
farming systems; there are plans to intercept groundwater DIN using filters” as a solution to
reducing run-off (Hay & Eagle, 2018, p. 36).
Perceptions of Causes and Pressure on Water Quality
Extension officers agreed (84.2%) with the statement that nutrient losses from cane growing
are having an effect on the water quality of local streams, rivers and waterways. However land
managers (42%) disagreed, responding that cane growing has no effect on the water quality
of local streams, rivers and waterways. By contrast, while 30% of land managers believe that
their activities are negatively affecting water quality, none of the extension officers believe that
land managers take this view. Just under 13% of land managers were unsure and 15% took
a neutral stance about nutrient losses affecting water quality and a small percent of extension
officers nominated that they didn’t know if cane farming has an impact on water quality.
A more detailed analysis is contained in the Report, Land Managers Decision Making about
Water Quality: Views from Extension Officers of the Wet Tropics, Queensland, Australia (Hay
& Eagle, 2018).
31
A full list of recommendations from the second round of data collection can be found in Section
8.5.
While the sample size represents 100% of extension officers invited to complete the survey
(N=31), the sample was restricted to one single cane growing region (the Wet Tropics) in North
Queensland. Therefore, the results may not be representative across all cane growing regions.
The potential for voluntary response bias is also acknowledged, where there is
overrepresentation of individuals that have strong opinions about extension activities.
However, it should be noted that such bias is normatively defensive because the second round
of the study has occurred within the explicitly extension officer group and that the research has
been conducted without concealment or fabrication (MacCoun, 1998).
6.3 Third Round (2018) Data Summary of Findings: Comparison
between first round (2016/17) and third round (2018) Data
Round Three data was collected in both the Wet Tropics and the Burdekin regions. Third
round data collection for both regions was undertaken from May to August 2018 repeating the
original full length survey (see Farr et al., 2016 for details of the questionnaire).
The Wet Tropics region survey was delivered face-to-face to land managers by extension
officers and the data was directly entered into iPads using Qualtrics Survey Software. In
addition thirty-six surveys were manually completed during face-to-face interviews and the
data was entered to the online database by a university research assistant. The data was
cleaned (words changed to numbers, ages grouped and anecdotal comments coded, etc.) and
imported to SPSS for analysis. A total of 118 surveys were collected in 2018. In 2017, 248
surveys were completed bringing the total number of surveys to 366.
Data from the first round (2016/17) of the Wet Tropics survey was compared with the third
round (2018) of Wet Tropics survey results to determine if there were any changes to behaviour
or attitude towards improving nutrient and run-off practices for improved water quality in the
GBR Basin. Below are the results from questions related to nutrient and run-off management
practices, results from structural equation modelling are presented in Section 5.3.
6.3.1.1 Factors that influence land manager decisions
In order to understand the factors that influence their decisions, land managers were asked to
identify the two most important things that they hoped to achieve for their farm or property.
32
Land managers responses were coded into first round and third round data, which resulted in
the same goals over the duration of the study. Land managers main goals are to improve their
land so that it can remain productive and sustainable into the future, while focussing on
maintaining their level of stewardship, highlighting a motivation to participate in good farming
practices.
Table 5: Wet Tropics land managers personal goals to achieve on farm/property
Goal 1 Goal 2
To leave the farm in a financial and sustainable position
Leave farm in a better condition than when we started farming 40 years ago
Improve production and quality of cane Pass property on to children in good condition
To grow a healthy efficient crop Maintaining the environment (stewardship of the land) maintain/increase soil health
6.3.1.2 Decision making drivers
The next question asked land managers how important they thought a set of 21 statements
were when making decisions about what to do on their farm or property (See Table 6). The
same set of questions were asked about three different practices. The participants were asked
to choose the importance of each statement on a scale of 1-extremely unimportant to 8 where
7 was equal to extremely important (essential) and 8 was equal to ‘I don’t know’, the number
4 was listed as neutral. A means test was applied to compare first and third round land
manager responses, followed by an independent samples t-test to establish any significant
difference in the responses.
Family, friends and other land manager influences
The first set of statements considered family, friends and other land manager influences when
making decisions. While all of the statements were indicated as important only ‘maintaining
family traditions and heritage’ (first round M=6.13, SD=0.88) and third round M=5.85, SD=1.05;
t(315)=2.34, p=.02, two tailed) and ‘maintaining good relations with other farmers/graziers in
the local area’ (first round M=5.64, SD=1.30 and third round M=5.27, SD=1.47; t(314)=2.08,
p=.03, two tailed) were statistically significant. Analysis of first round data found that
‘maintaining good relations with other farmers/graziers in the local area’ was important but not
significant (see Farr et al., 2016; Farr et al., 2017b for results). The current results may indicate
the respondents have changed the way they maintain relationships with other farmers or
graziers. There was no significant difference between the other means.
Financial influencers
Similarly, all of the statements that considered financial influences were indicated as important.
‘Maximising farm profits’ was rated as a somewhat important influencer in both the first round
(M=6.53, SD=0.85) and the third (M=6.55, SD=0.79) round of data collection, when making
decision about land management on the farm or property. However, while ‘servicing debt’ first
round (M=6.10, SD=1.40) and the third round (M=5.80, SD=1.42) was indicated as less
important than maximising farm profits, there was a higher agreeance that ‘servicing debt’ was
still an important influencer to decisions about land management. An independent t-test found
no significant difference between scores from first round data to scores from third round data
indicating that maximising farm profits and servicing debt are ongoing influencers when making
decisions about what to do on the farm/property.
33
Land managers making their own decisions, testing and sharing new ideas and having
time to pursue hobbies when making decisions about the farm/property
The next set of statements provide land manager responses about making their own decisions,
testing and sharing new ideas and having time to pursue hobbies when making decisions about
the farm/property. While all of the statements were indicated as important, ‘having efforts
recognised by the wider community’ (first round M=4.67, SD=1.72 and third round M=5.10,
SD=1.45; t(315)=-1.92, p=.05, two tailed) and ‘sharing new ideas with others’ (first round
M=5.97, SD=1.09) and third round M=5.65, SD=1.21; t(107)=2.00, p=.05, two tailed) were
statistically significant. While ‘having efforts recognised by the wider community’ was the least
important factor for both rounds of data collection, the factor was considered more important
in the third round of data collection. Similarly, the results indicate that the importance of
‘sharing new ideas with others’ has slightly increased as an influencer when making decision
about what to do on the farm/property. There was no significant difference between the other
means across the two data collection periods.
Land management influencers
The next set of statements consider land management influences when making decisions.
While all of the statements were indicated as important ‘minimising sediment run-off and/or
nutrient losses’ scores (first round M=6.55, SD=.77) and third round M=6.32, SD=0.95;
t(312)=2.05, p=.04, two tailed) was significant, indicating that minimising run-off has increased
in importance between first round and third round data collection. There was no significant
difference between the other means across the two data collection periods.
Farming practices
Land managers rated ‘leaving the land in better condition than it was when they first started
managing it’ and ‘maintaining and improving water supplies and storages’ were rated as
important to extremely important to land managers when making decisions on their property.
However, there was no statistical difference in importance between the first round and the third
round of data collection. Whereas there was a statistical difference for minimising sediment
run-off and or nutrient losses between first round (M=6.55; SD=0.77) and third round data
(M=6.32, SD=0.95; t(312)=2.61, p=.04, two tailed), where land managers rated it as important
to making decisions in the third round of data collection as they did in the first round.
Safeguarding local waterways, native plants and animals and the Great Barrier Reef
The final set of statements indicate that safeguarding local waterways, the Great Barrier Reef
(GBR) and native plants and animals are important to land managers. While land managers
highly agree with safeguarding native plants and animals, it was less important than
safeguarding local waterways and the GBR. An independent t-test highlighted a significant
difference for ‘helping to safeguard local waterways’ scores for first round (M=6.40, SD=.89)
and third round (M=6.07, SD=1.11; t(313)=2.57, p=.01, two tailed). The magnitude of
difference in the means (mean difference = .31, 95% CI: .08 to .54) was small to moderate (eta
squared = .021). Similarly, an independent t-test highlighted a significant difference for ‘helping
to safeguard the GBR’ scores for first round (M=6.42, SD=.81) and third round (M=6.11,
SD=1.08; t(313)=2.61, p=.01, two tailed). The magnitude of difference in the means (mean
difference = .32, 95% CI: .08 to .58) was also small to moderate (eta squared = .021). Both
results indicate that safeguarding local waterways and the GBR are important influencers when
land managers are making decisions about what to do on their farm/property.
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Table 6: Wet Tropics land manager responses decision making drivers
1st Round 3rd Round
n Mean SD n Mean SD
Maintaining physical and mental health of family 246 6.59 0.86 71 6.41 1.09
Spending face-to-face time with family and friends
246 6.19 1.01 71 6.11 1.01
Maintaining good relations with other farmers/graziers in the local area*
246 6.13 0.88 71 5.85 1.05
Keeping in contact with family and friends in other ways (e.g. via phone, through social media)
243 5.79 1.35 71 5.46 1.26
Maintaining family traditions and heritage* 245 5.64 1.30 71 5.27 1.47
Maximising farm profits (income minus costs) 245 6.53 0.85 71 6.55 0.79
Keeping a stable (steady) cash-flow 246 6.48 0.87 71 6.48 0.75
Keeping farm costs low 246 6.43 0.95 71 6.38 0.99
Minimising risk (of very high costs or very low income)
246 6.26 1.01 71 6.34 0.92
Servicing debt 240 6.10 1.40 71 5.80 1.42
Being able to make your own decisions about your farm/property
246 6.59 0.79 71 6.56 0.71
Learning about and testing new ways of doing things on your farm/property
246 6.23 0.86 71 6.14 0.87
Sharing new ideas with others* 246 5.97 1.09 72 5.65 1.21
Having time to pursue hobbies 246 5.23 1.49 71 5.39 1.37
Having efforts recognised by the wider community*
245 4.67 1.72 72 5.10 1.45
Leaving the land/farm in better condition than it was when you first started managing it
245 6.59 0.76 71 6.65 0.61
Minimising sediment run-off and/or nutrient losses*
243 6.55 0.77 71 6.32 0.95
Maintaining/improving water supplies and storages
206 5.99 1.73 72 5.93 1.71
Helping to safeguard local waterways* 243 6.42 0.81 72 6.11 1.08
Helping to safeguard the Great Barrier Reef* 243 6.40 0.89 72 6.07 1.10
Helping to safeguard native plants and animals 242 5.99 1.04 72 5.76 1.24
Note: 1=strongly disagree, 7=strongly agree, *=significant at 5% level
6.3.1.3 Nutrient Management Practices
Land managers were asked to answer a series of questions about their nutrient management
practices. The responses from the first round of data were compared to responses from the
third round of data to identify any changes in nutrient management practices.
Calculating Fertiliser Application Rates
When asked how the respondents calculate their fertiliser application rates, the majority in both
first and third round data collection selected that they tailor their fertiliser rates to different parts
of the property (see Table 7). Just over one quarter of respondents in the first round and one
quarter of respondents in third round tailor fertiliser rates to different parts of their property.
There is a slight increase in participants that are using industry standards in the third round of
data collection compared to the first round. Twenty percent in the first round and 16% in the
35
second round of data collection do something else (Other) to calculate their fertiliser application
rates (see Table 8).
The remaining respondents in each year are estimating fertiliser rates from farm yield or they
are applying more or less depending on performance of the block. Nearly one quarter of
respondents in the first round of data collection and 30% of respondents in the third round
selected that their advisor calculates fertiliser application rates for them.
Table 7: Wet Tropics participant responses to the question 'How do you calculate fertiliser application
rates?"
1st Round 3rd Round n Percent n Percent
I tailor my fertiliser rates to different parts of the property 133 28.7 40 25.6
My advisor does this for me**(Table 9 below) 114 24.6 46 29.5
Other. Please tell us what you do*(Table 8 below) 97 21.0 25 16.0
I use industry standard rates for district yield potential, and use that amount on all parts of my farm 96 20.7 34 21.8
I estimate amounts from my farm yield and use that amount on all parts of my farm 13 2.8 5 3.2
I use more fertiliser on under-performing (low yield) blocks than on other blocks 7 1.5 2 1.3
I use more fertiliser on high – performing (high yielding) blocks 3 0.6 4 2.6
Total 462 100 156 100
The responses from ‘Other. Please tell us what you do’ in Table 7 above were coded into ten
themes, see Table 8 below. More land managers were using six easy steps to calculate their
fertiliser application rates as an alternative measure for fertiliser application in first round data
collection (47.4%) than in third round (36.0%). This is reflective of the six easy steps
workshops attended by more land managers in the first round of data collection than in the
third round. Land managers were using experience or historical data more in the first round of
data collection than in the third round, which may indicate a change in activities more in line
with best management practice. Less land managers reported using ‘Other’ ways to calculate
fertiliser application rates, such as soil tests, genetic evaluation systems and nutrient
management plans are decreasing as an alternative, whereas using best management
practices, mill mud, organic matter or alternative crops has increased. Thirty two percent of
land managers who nominated that they use an ‘Other’ way to calculate fertiliser application
rates are using Smartcane BMP and 16% are using mill mud, organic matter or alternative
crops as part of their fertiliser application management, indicating a change in the way that
fertiliser application rates are calculated.
36
Table 8: Wet Tropics land manager responses to 'How do you calculate fertiliser application rates? - Other'
Other. Please tell us what you do* 1st Round 3rd Round
n Percent n Percent
6 Easy Steps 46 47.4 9 36.0
Experience/Historical 13 13.4 0 0.0
Soil Tests 12 12.4 1 4.0
GES (Genetic Evaluation System) 11 11.3 1 4.0
Agronomist 4 4.1 0 0.0
Mill mud/ Organic Matter/Alternative Crops 3 3.1 4 16.0
Smartcane BMP 2 2.1 8 32.0
Variable rate box 2 2.1 2 8.0
Nutrient Management Plan 1 1.0 0 0.0
Other* 3 3.1 0 0.0
Total 97 100 25 100
*Experimental low rates using biology; For planting the compactor puts on the same rate across the property; I trail the ratoon rate; Tailor to different varieties
To establish who their advisor was (Table 7 above), for those land managers who selected
that their ‘My advisor does this for me’ a cross tabulation between ‘advice land managers follow
most when calculating fertiliser rates’ and ‘how do you calculate fertiliser application rates -
my advisor does this for me was performed (see Table 9). In both first and third round data
collection, the land manager’s main advisor was industry extension advisors, followed by
private agronomists and researchers.
Table 9: Cross tabulation of Wet Tropics land managers ‘Advice land managers follow most when
calculating fertiliser rates’ and ‘how do you calculate fertiliser application rates - my advisor does this for me’
Advice followed most when calculating fertiliser rates - who? My advisor does this for me
1st Round 3rd Round
n Percent n Percent
Industry extension advisors (e.g. from SRA [BSES], Production Boards, Productivity Services group)
48 45.7 18 38.3
Private Agronomists 23 21.9 18 38.3
Researchers 8 7.6 4 8.5
Family who are also cane farmers 4 3.8 2 4.3
Other extension officers. From where? 4 3.8 1 2.1
Cane Growers (the organisation) 3 2.9 0 0.0
Other cane farmers 1 1.0 0 0.0
Landcare 1 1.0 1 2.1
Regional cane association (e.g. from Kalamia, Invicta, Inkerman, Tully Sugar)
0 0.0 0 0.0
People from NQ Dry Tropics/TERRAIN 0 0.0 1 2.1
Other. Who?* 13 12.4 2 4.3
Total 92 100 45 100
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Where land managers nominated an ‘Other. Who?’ (Table 10) as advice they follow when
calculating fertiliser rates, they nominated fertiliser companies and resellers, their own
experience and advice from best management practices in both rounds of data collection as
‘other’ advice land managers follow.
Table 10: Advice followed most when calculating fertiliser rates - *Other. Who?
Advice followed most when calculating fertiliser rates - *Other. Who?
1st Round 3rd Round
n Percent n Percent
Fertiliser Company/Reseller 47 64.4 12 66.7
Myself (Experience & Knowledge) 19 26.0 4 22.2
Best Practice Management (6ES, Smartcane [BMP modules], Soil Tests)
4 5.5 2 11.1
Extension Staff 2 2.7 0 0.0
Financial Constraints 1 1.4 0 0.0
Total 73 100 18 100
Table 10 ‘Other. Who?’ indicates that more than 60% of land managers in both first and third
year data collection nominated fertiliser resellers as the advisor they follow most when
calculating fertiliser rates. This finding highlights fertiliser resellers as highly influential to land
managers when making decisions about calculating fertiliser rates. Anecdotal comments from
land managers (and extension officers) during the study period have confirmed this influence
as a reason for not following best management practice in fertiliser application. Several land
managers (and extension officers) have also stated that land managers will ignore best
management practice if the reseller incentivises fertiliser purchases e.g. buy two tonnes of
fertiliser and get one tonne free.
Advice land managers follow most when calculating fertiliser application rates
Land managers were asked to rank from 1= most important to 12=least important whose
advice they follow most when calculating fertiliser application rates. A cross tabulation between
‘advice land managers follow when calculating fertiliser rates’ and ‘round of data collection’
compared responses from the first and third rounds of data collection (see Table 11 and Table
12).
In the first round data collection, land managers found advice from industry extension most
important, followed by private agronomists, other – who?*, researchers then family who are
also cane farmers. The ‘Other. Who?’ selection highlights that land managers found advice
important from their own experience, fertiliser companies and resellers, best management
practice, from local agronomists or agricultural productivity boards and through financial and/or
environmental constraints. ‘Other extension officers, from where?’ also highlights resellers,
government agency and mills as important advisors. ‘People from government departments,
which departments?’ are highlighted as being primarily from the Department of Agriculture and
Fisheries (DAF).
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Table 11: Advice Wet Tropics land managers follow when calculating fertiliser rates, ranked 1 most important to 12 least important – 1st Round Data Collection
Advisor 1st Round
Rank 1 2 3 4 5 6 7 8 9 10 11 12 Total
Industry extension advisors (e.g. from SRA [BSES], Production Boards, Productivity Services group)
110 43 11 7 2 0 0 1 0 0 0 0 174
Private Agronomists 38 29 19 4 7 2 0 0 0 0 0 0 99
Other. Who?* 31 23 6 4 1 0 0 0 0 0 0 1 66
Researchers 18 22 17 13 9 0 1 0 1 0 0 0 81
Family who are also cane farmers
13 20 13 6 5 1 0 1 0 0 0 0 59
Other extension officers. From where?**
8 15 8 8 8 0 1 0 0 1 3 0 52
Other cane farmers 6 20 35 12 11 1 1 0 0 1 0 0 87
Cane Growers (the organisation)
5 9 14 19 13 0 1 0 1 0 0 0 62
People from government departments. Which departments?***
1 2 6 3 4 1 0 1 1 2 1 2 24
Landcare 1 1 1 0 3 1 0 1 0 2 0 0 10
People from NQ Dry Tropics/TERRAIN
0 2 3 3 2 0 1 0 1 1 1 0 15
Regional cane association (e.g. from Kalamia, Invicta, Inkerman, Tully Sugar)
0 0 2 0 0 1 1 1 1 1 0 0 7
*Other. Who? (Number of responses): their own experience (52), fertiliser companies and resellers (12), best management practice (7), from local agronomists (1) and through financial and/or environmental constraints (1) **Other Extension, from where: Resellers (14), Government: DAFF, DPI (14), Mill (10), productivity board/Industry (8), best management practice, (1), agronomist (1), and researcher (1). *** Government Departments: DAF (7), DPI (2), DERM (1), DSITI (1), DIS (1), EHP (1), and SRA (1)
In the third round data collection, land managers also placed the most importance on industry
extension officers in the first instance, then researchers, private agronomists, Cane Growers
(the association) and other cane farmers. ‘Other. Who?’ also highlighted fertiliser companies
and resellers, land manager own experience, local agronomists and productivity boards as
advisors that they follow most. ‘Other extension, from where?’ and ‘People from government
departments. Which departments?’ responses are similar to first round data collection (see
Table 12).
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Table 12: Advice Wet Tropics land managers follow when calculating fertiliser rates, ranked 1 most important to 12 least important – 3rd Round Data Collection
Advisor 3rd Round
Rank 1 2 3 4 5 6 7 8 9 10 11 12 Total
Industry extension advisors (e.g. from SRA [BSES], Production Boards, Productivity Services group)
46 16 14 9 6 1 0 3 0 4 1 0 100
Researchers 10 22 14 11 3 2 4 3 8 7 3 2 89
Private Agronomists 29 10 7 8 6 1 3 8 10 1 1 0 84
Cane Growers (the organisation)
2 7 12 14 8 17 15 3 2 0 0 1 81
Other cane farmers 1 8 20 13 10 11 4 5 5 2 0 1 80
Family who are also cane farmers
7 18 4 8 14 9 9 2 2 0 2 1 76
Other extension officers. From where?**
3 11 10 2 5 6 4 1 3 4 25 2 76
Other. Who?* 7 7 5 5 9 2 3 5 7 4 2 18 74
Landcare 1 1 3 0 1 4 1 8 9 32 14 0 74
People from government departments. Which departments?***
0 0 1 4 0 4 1 5 4 7 7 41 74
People from NQ Dry Tropics/TERRAIN
1 1 1 1 6 9 7 18 10 7 11 1 73
Regional cane association (e.g. from Kalamia, Invicta, Inkerman, Tully Sugar)
1 1 3 7 7 7 19 8 10 2 3 2 70
*Other. Who? (Number of responses): fertiliser companies and resellers (9), their own experience (6), from local agronomists (2) and through agricultural productivity boards (1) **Other Extension, from where: Extension officer (7), productivity board/Industry (4), mill (3), resellers (2), and Government: DAFF, DPI (2). *** Government Departments: DAF (2), DoE (1), DIS (1), and EHP (1)
Regional cane associations, Landcare, people from government departments and people from
natural resource management groups were nominated as least important to follow advice in
both first round and third round data collection (see Table 11 and Table 12).
It is important to note the high influence that networks have on land manager decisions, as
they may identify barrier to practice change. The findings support previous recommendations
for a land manager network analysis to ensure that information gatekeepers and opinion
leaders influence future water quality communication strategies (see Hay & Eagle, 2018).
Attitudes and motivations associated with calculating fertiliser application rates
The next question asked participants how important they thought a set of listed statements
were to land managers when making decisions about calculating fertiliser rates. The
participants were asked to choose the importance of each statement on a scale of 1-strongly
disagree to 7 strongly agree, with 4 being neutral.
40
The first set of statements considered decision influencers when making decisions about
calculating fertiliser rates. The data indicates that land managers decisions are somewhat
influenced by ‘farmers they respect’ with regard to fertiliser rate calculations in both first
(M=5.77, SD=1.73) and third round (M=5.03, SD=1.68) data. The respondents somewhat
disagree in both first round (M=3.64, SD=2.37) and third round (M=3.38, SD=2.22), that other
land managers in the area would not have the technical knowledge to calculate fertiliser rates.
However, a large percentage (60%) use resellers to calculate their fertiliser rates (see Table
9), therefore this may not truly reflect the confidence of the land managers to calculate fertiliser
rates. Land managers disagreed in both first round (M=2.66, SD=2.26) and third round
(M=2.84, SD=2.25) data collection that land managers in the region would not be able to afford
to use the systems to calculate fertiliser rates, indicating that the systems mentioned are
affordable. Land managers also did not agree that they were being forced to use the methods,
see Table 13. There were no significant difference in scores for each statement.
Table 13: Wet Tropics land manager attitudes and motivations associated with calculating fertiliser
application rates
1st Round 3rd Round
n Mean SD n Mean SD
The farmers I respect most do this 221 5.77 1.73 69 5.93 1.68
Most farmers in this region would not have the technical knowledge to do this
213 3.64 2.37 69 3.38 2.22
Most farmers in this region would not be able to afford to use this system for calculating fertiliser rates
214 2.66 2.26 69 2.84 2.25
I only do this because I am forced to. Who/what is forcing you?
212 2.05 1.92 69 2.12 1.73
Note: 1=strongly disagree, 7=strongly agree, *=significant at 5% level
The second set of statements ask the land manager to read the statement and respond how using
their method for calculating fertiliser rates measures when compared to other ways of calculating
fertiliser rates.
While all statements have high agreement (see Table 14) ‘the best way to meet my own personal
goals’ and to be ‘the least time consuming’ compared to other ways of calculating fertiliser rates are the
most significant motivators for using the method that the land manager is using. It is interesting to note
that in the third round of data collection land managers were more neutral (M=4.96, SD=1.81) about
their way of calculating fertiliser rates being ‘the least time consuming’ than the first round (M=5.50,
SD=1.55). This may be due to increased awareness of growers’ legal obligations towards best
management practices, given that 32% of land managers are using Smartcane BMP in the third round
of data collection compared to 2.1% in the first round of data collection.
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Table 14: Compared to other ways of calculating fertiliser rates, what motivates Wet Tropics land managers to use the system that they use?
1st Round 3rd Round
n Mean SD n Mean SD
The best way to meet my own personal goals* 217 6.26 1.04 69 5.96 1.27
The most effective way of controlling nutrient loss from my property
218 6.24 1.16 69 6.12 1.19
The best way to maintain good cash-flow 219 6.17 1.04 69 5.88 1.16
The best way to reduce business risk 218 6.16 1.07 69 5.93 1.13
The least time-consuming (or labour intensive)* 218 5.50 1.55 69 4.96 1.81
Note: 1=strongly disagree, 7=strongly agree, *=significant at 5% level
An independent t-test highlighted a significant difference for ‘the best way to meet my own
personal goals’ scores for first round (M=6.26, SD=1.04) and third round (M=5.96, SD=1.27;
t(284)=2.02, p=.04, two tailed). The magnitude of difference in the means (mean difference
=.30, 95% CI: .01 to .61) was small (eta squared =.01). The result indicates that while,
calculating fertiliser rates to meet the land managers own personal goals had decreased in
importance between first round and third round data collection, only 1% of the variance was
explain by time between the data collection points. The effect was similar for ‘the least time
consuming’ factor. There was no significant difference between the other means across the
two data collection periods.
Has calculating fertiliser application rates changed?
To establish whether there was a change in the way land managers calculate fertiliser
application rates between first and third round data collection, a multiple response cross-
tabulation was performed (see Table 13). The land manager unique identification number was
used to identify growers in each round of data collection (1=Grower First Round and 3=Same
Grower Third Round). There were 111 growers who responded to the statements in first round
and 93 who responded in the third round of data collection. Results in Table 15 indicate that
there has been a change in the way land managers calculate fertiliser application. For example
28% of third round land managers are using industry standard rates for district yield potential
compared to first round land managers (17.1%).
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Table 15: Comparison between 'How first and third round Wet Tropics land managers calculate fertiliser application rates’
How do you calculate fertiliser application rates?
Have you completed this survey before?
Grower 1st Round
Same Grower 3rd Round
Total
I use industry standard rates for district yield potential, and use that amount on all parts of my farm
Count 19 26 45
% within $FAPP 42.2% 57.8%
% within CompBefore 17.1% 28.0%
% of Total 9.3% 12.7% 22.1%
I use more fertiliser on high – performing (high yielding) blocks
Count 0 4 4
% within $FAPP 0.0% 100.0%
% within CompBefore 0.0% 4.3%
% of Total 0.0% 2.0% 2.0%
I estimate amounts from my farm yield and use that amount on all parts of my farm
Count 3 4 7
% within $FAPP 42.9% 57.1%
% within CompBefore 2.7% 4.3%
% of Total 1.5% 2.0% 3.4%
My advisor does this for me Count 30 32 62
% within $FAPP 48.4% 51.6%
% within CompBefore 27.0% 34.4%
% of Total 14.7% 15.7% 30.4%
I use more fertiliser on under-performing (low yield) blocks than on other blocks
Count 6 2 8
% within $FAPP 75.0% 25.0%
% within CompBefore 5.4% 2.2%
% of Total 2.9% 1.0% 3.9%
I tailor my fertiliser rates to different parts of the property
Count 53 25 78
% within $FAPP 67.9% 32.1%
% within CompBefore 47.7% 26.9%
% of Total 26.0% 12.3% 38.2%
Total Count 111 93 204
% of Total 54.4% 45.6% 100.0%
Percentages and totals are based on responses. a. There are not enough (less than 2) multiple response groups for pairing. Percentages are based on responses, but no pairing is performed. b. Dichotomy group tabulated at value 1.
While none of the land managers reported using more fertiliser on high yielding blocks in first
round data, 4.3% of land managers reported using this technique to calculate fertiliser
application in the third round. Similarly, third round land managers (4.3%) are estimating
amounts from their farm yield and then using that amount on all parts of their farm.
A slightly higher proportion of third round land managers (34.4%) are using their advisor to
calculate fertiliser rates than first round land managers (27%). By contrast, less third round
land managers (2.2%) are using more fertiliser on low yielding blocks than on other blocks
than first round land managers (5.4%). A lower proportion of third round land managers
(26.9%) are tailoring their fertiliser rates to different parts of their property compared to first
round land managers (47.7%). While the data in Table 15 indicates changes in the way that
43
land managers are calculating their fertiliser application rates, the results cannot determine if
land managers are using best practice management techniques to calculate fertiliser rates or
some other method.
6.3.1.4 Run-off Management Practices
Land managers were asked to answer a series of questions about their run-off management
practices. The responses from the first round of data were compared to responses from the
third round of data to identify any changes in run-off management practices.
Handling run-off
A multiple response analysis indicates that nearly one third of land managers are following
conventional run-off management practices such as using recycle pits and sediment traps and
one third are using the superseded or outdated practice of not capturing run-off. However, this
may be due to identifying run-off as being from irrigation which is not widely used in the wet
tropics. Less than 1% of land managers are using their recycle pits with adequate pumping
capacity to recycle water. Other practices are either meeting minimum expectations or are
current practices as promoted by the industry (ABCD Framework, Drewry, Higham, & Mitchell,
2008; Trendell, 2013) (see Table 16).
Table 16: Wet Tropics land manager responses to the question 'how do you handle run-off from rainfall or
irrigation?’
ABCD Framework
1st Round 3rd Round
n Percent n Percent
I have recycle pits/Sediment traps C 99 29.9 4 3.8
I do not capture run-off D 93 28.1 11 10.6
I have recycle pits and have adequate pumping capacity to recycle the water
B 3 0.9 7 6.7
Other. Please tell us what you do* C-B 136 41.1 82 78.8
Total 331 100 104 99.9 ABCD
Framework 1st Round 3rd Round
Other* n Percent n Percent
Sediment trap C 13 9.6 11 13.4
Grass and Drains C-B 53 39.0 45 54.9
Buffer Zones/Riparian Boundary/Revegetation C-B 17 12.5 7 8.5
Contouring C-B 7 5.1 4 4.9
Laser levelled, silt trap, grass C-B 6 4.4 7 8.5
Grass and trash blanket C 26 19.1 4 4.9
Natural drainage filter C-B 6 4.4 1 1.2
Rock walls C-B 4 2.9 0 0.0
Other** C-B 4 2.9 3 3.7
Total 136 100 82 100
**First Round: Do not irrigate + have 1 metre+ rainfall, below sea level/next to subdivision - run-off is heavy due to streets and houses, timing of cultivation, using subsurface + liquid fertiliser that slows down N losses. Third Round: controlled drops from headland to drains, natural bio-reactors, I carefully control run-off from within & from paddocks
44
Advice land managers follow most when handling run-off
Land managers were asked to rank from 1= most important to 12=least important whose
advice they follow most when handling run-off. A cross tabulation between ‘advice land
managers follow when handling run-off’ and ‘round of data collection’ compared responses
from the first and third rounds of data collection (see Table 17 and Table 18).
In the first round of data collection, industry extension officers, private agronomists and other
(includes their own experience, fertiliser resellers and best management practice) rank the
highest form of advice that was followed by land managers who grow sugar cane in the
Burdekin. Regional cane associations, people from NRMs and Landcare ranked the lowest
form of advice followed in the first round of data collection.
Table 17: Advice Wet Tropics land managers follow when handling run-off, ranked 1 most important to 12
least important – 1st Round Data Collection
Advisor 1st Round
Rank 1 2 3 4 5 6 7 8 9 10 11 12 Total
Industry extension advisors (e.g. from SRA [BSES], Production Boards, Productivity Services group)
110 43 11 7 2 0 0 1 0 0 0 0 174
Private Agronomists 38 29 19 4 7 2 0 0 0 0 0 0 99
Other. Who? 31 23 6 4 1 0 0 0 0 0 0 1 66
Researchers 18 22 17 13 9 0 1 0 1 0 0 0 81
Family who are also cane farmers
13 20 13 6 5 1 0 1 0 0 0 0 59
Other extension officers. From where?
8 15 8 8 8 0 1 0 0 1 3 0 52
Other cane farmers 6 20 35 12 11 1 1 0 0 1 0 0 87
Cane Growers (the organisation)
5 9 14 19 13 0 1 0 1 0 0 0 62
People from government departments. Which departments?
1 2 6 3 4 1 0 1 1 2 1 2 24
Landcare 1 1 1 0 3 1 0 1 0 2 0 0 10
People from NQ Dry Tropics/TERRAIN
0 2 3 3 2 0 1 0 1 1 1 0 15
Regional cane association (e.g. from Kalamia, Invicta, Inkerman, Tully Sugar)
0 0 2 0 0 1 1 1 1 1 0 0 7
*Other. Who? (Number of responses): their own experience (52), fertiliser companies and resellers (12), best management practice (7), agronomist (1) and from financial or environmental constraints (1) **Other Extension, from where: reseller/fertiliser supplier or company extension officer (14), Government agency extension officer (14), mill (10), agricultural productivity board/industry (8), agronomist (1) researcher (1). *** Government Departments: DAF/DPI (7), DERM (1), DSITI (1), SRA(1)
Similarly, in the third round of data collection industry extension, private agronomists and
researchers were ranked as most important as advisors. However, family who are also cane
45
farmers was ranked as more important in third round than in the first round of data collection.
While people from government departments was ranked 9th in the first round of data collection,
they were ranked 12th in the third round, indicating a change in trust of advice from people in
government departments. However, on an individual level in the first round, people from
government departments were ranked as the third most followed advisor, see Table 17.
Table 18: Advice Wet Tropics land managers follow when handling run-off, ranked 1 most important to 12
least important – 3rd Round Data Collection
Advisor 3rd Round
Rank 1 2 3 4 5 6 7 8 9 10 11 12 Total
Industry extension advisors (e.g. from SRA [BSES], Production Boards, Productivity Services group)
46 16 14 9 6 1 0 3 0 4 1 0 100
Private Agronomists 29 10 7 8 6 1 3 8 10 1 1 0 84
Researchers 10 22 14 11 3 2 4 3 8 7 3 2 89
Family who are also cane farmers
7 18 4 8 14 9 9 2 2 0 2 1 76
Other. Who? 7 7 5 5 9 2 3 5 7 4 2 18 74
Other extension officers. From where?
3 11 10 2 5 6 4 1 3 4 25 2 76
Cane Growers (the organisation)
2 7 12 14 8 17 15 3 2 0 0 1 81
Other cane farmers 1 8 20 13 10 11 4 5 5 2 0 1 80
Landcare 1 1 3 0 1 4 1 8 9 32 14 0 74
People from NQ Dry Tropics/TERRAIN
1 1 1 1 6 9 7 18 10 7 11 1 73
Regional cane association (e.g. from Kalamia, Invicta, Inkerman, Tully Sugar)
1 1 3 7 7 7 19 8 10 2 3 2 70
People from government departments. Which departments?
0 0 1 4 0 4 1 5 4 7 7 41 74
*Other. Who? (Number of responses): their own experience (6), fertiliser companies and resellers (9), agronomist (2) and from agricultural productivity board (1) **Other Extension, from where: reseller/fertiliser supplier or company extension officer (2), Government agency extension officer (2), mill (3), agricultural productivity board/industry (4), BMP (1), agronomist (1) extension officer (7). *** Government Departments: DAF (2), DoE (2), DIS (1)
Attitudes and motivations associated with handling run-off
The next question asked participants how important they thought a set of listed statements
were to land managers when making decisions about handling run-off. The participants were
asked to choose the importance of each statement on a scale of 1-strongly disagree to 7
strongly agree, with 4 being neutral.
The first set of statements considers influences when making decisions about handling run-
off. The data indicates that land managers agree that their decisions are influenced by ‘farmers
they respect’ with regard to handling run-off in both first (M=5.89, SD=1.58) and third round
46
(M=5.97, SD=1.40) data. The land managers also agree that the ‘people/organisations whose
advice they follow most think that they should do this’ influences their decisions about handling
run-off in both first round (M=5.74, SD=1.84) and third round (M=5.86, SD=1.63) data
collection. Land managers somewhat disagreed in both first round (M=3.31, SD=2.34) and
third round (M=3.68, SD=2.46) data collection that land managers in the region would not be
able to afford to use the systems to calculate fertiliser rates, indicating that the systems
mentioned are affordable. The respondents somewhat disagree in both first round (M=3.10,
SD=2.30) and third round (M=2.94, SD=2.12), that other land managers in the area would not
have the technical knowledge to handle run-off, indicating that they would have the technical
knowledge. Land managers also strongly disagreed that they were being forced to use the run-
off handling methods, see Table 19. There were no significant difference in scores for each
statement.
Table 19: Wet Tropics land manager attitudes and motivations associated with handling run-off
1st Round 3rd Round
n Mean SD n Mean SD
The farmers I respect most do this 192 5.89 1.58 69 5.97 1.40
The people/organisations whose advice I follow most think I should do this
189 5.74 1.84 69 5.86 1.63
Most farmers in this region would not be able to afford to use this system for handling run-off
192 3.31 2.34 69 3.68 2.46
Most farmers in this region would not have the technical knowledge to do this
192 3.10 2.30 69 2.94 2.12
I only do this because I am forced to. Who/what is forcing you?
184 1.98 2.06 69 1.80 1.68
Note: 1=most important, 12=least important, *=significant at 5%
The second set of statements ask the land manager to read the statement and respond how
using their method for handling run-off measured when compared to other ways of handling
run-off.
While all statements have a high level of agreement (see Table 20) ‘the best way to meet my
own personal goals’, ‘the most effective way of controlling nutrient loss from my property’, ‘the
best way to maintain good cash flow and ‘the best way to reduce business risk’ are the most
significant motivators for using the method for handling run-off that the land manager is using.
In both rounds of data collection land managers somewhat agreed that the way they handled
run-off was the ‘least time consuming’.
Table 20: Compared to other ways of handling run-off, what motivates Wet Tropics land managers to use
the system that they use?
1st Round 3rd Round
n Mean SD n Mean SD
The best way to meet my own personal goals 190 6.33 1.04 69 6.07 1.23
The most effective way of controlling nutrient loss from my property
188 6.33 1.04 69 6.19 1.32
The best way to maintain good cash-flow 190 6.08 1.29 69 5.84 1.69
The best way to reduce business risk 191 6.04 1.28 69 5.86 1.46
The least time-consuming (or labour intensive) 191 5.67 1.67 69 5.46 1.80
Note: 1=most important, 12=least important, *=significant at 5%
47
An independent t-test highlighted a significant difference for ‘the least time consuming’ score
for first round (M=5.50, SD=1.56) and third round (M=4.96, SD=1.81; t(101)=2.22, p=.03, two
tailed). The magnitude of difference in the means (mean difference =.30, 95% CI: .01 to .61)
was small (eta squared =.01). The results indicate that while handling run-off is the least time
consuming, it had increased in importance between first round and third round data collection,
only 1% of the variance was explain by time between the data collection points. This may be
due to land managers not capturing run-off from irrigation, which is not widely used in the Wet
Tropics region. There was no significant difference between the other means across the two
data collection periods.
Has handling run-off practices changed?
To establish whether there was a change in the way land managers handle run-off between
first and third round data collection, a multiple response cross-tabulation was performed (see
Table 21). The land manager unique identification number was used to identify growers in
each round of data collection (1=Grower First Round and 3=Same Grower Third Round).
There were 61 growers who responded to the statements in first round and 12 who responded
in the third round of data collection.
While the response rate of those who completed the survey in both rounds is low, the data
indicates that less land managers are using recycle pits in third round (33.3%) than in first
round (65.6%) data collection. More land managers reported not capturing run-off in third
round (50%) compared to first round (36.1%). More land managers reported having recycle
pits with adequate pumping capacity to recycle the water in third round (16.7%) than in first
round (1.6%) data collection. While the data in Table 21 indicates changes in the way that land
managers are handling run-off, the results cannot determine if land managers are using best
practice management techniques to handle run-off or some other method.
Table 21: Comparison between 'How first and third round Wet Tropics land managers handle run-off’
How do you handle run-off? Have you completed this survey before?
Grower 1st Round
Same Grower 3rd Round
Total
I have recycle pits/Sediment traps
Count 40 4 44
% within $Run-off 90.9% 9.1%
% within CompBefore 65.6% 33.3%
% of Total 54.8% 5.5% 60.3%
I do not capture run-off
Count 22 6 28
% within $Run-off 78.6% 21.4%
% within CompBefore 36.1% 50.0%
% of Total 30.1% 8.2% 38.4%
I have recycle pits and have adequate pumping capacity to recycle the water
Count 1 2 3
% within $Run-off 33.3% 66.7%
% within CompBefore 1.6% 16.7%
% of Total 1.4% 2.7% 4.1%
Count 61 12 73
% of Total 83.6% 16.4% 100.0%
Percentages and totals are based on responses. a. Dichotomy group tabulated at value 1.
48
6.3.1.5 Other Innovative Run-off Practices
Land managers were asked if they used any other innovative practices to manage nitrogen
and/or run-off. Sixty three percent selected yes that they thought they were using innovative
practices in first round data collection and 33.9% selected yes in the third round. However,
when matching responses to the ABCD Framework, the practices used meet conventional to
best management practice expectations. A list of anecdotal comments from land managers
describing the practices are included in Appendix 3.
Table 22: Other innovative practices - anecdotal comments from Wet Tropics land managers,
coded (see Appendix 3 for examples)
Do you use any other innovative practices to manage nitrogen and/or run-off?
1st Round 3rd Round
n Percent n Percent
Yes 147 63.6 40 33.9
No 84 36.4 28 41.2
Total 231 100 68 100
Coded Responses to Innovative Practices (see examples in Appendix 3)
ABCD Framework
1st Round 3rd Round
n Percent n Percent
Fertiliser/Bio Fertiliser C, B 75 50.3 29 52.7
Alternative Crops/Irrigation C, B 13 8.7 11 20.0
Headlands/Drains/Recycle Pits/Laser Levelling B 17 11.4 5 9.1
Green Trash Blanket/Composting C, B 14 9.4 4 7.3
Stool Splitting Mixed Method C 29 19.5 4 7.3
Best Management Practices C, B 1 0.7 2 3.6
Total 149 100 55 100
6.3.1.6 Perceptions of Causes and Pressure on Water Quality
Land managers were asked to agree (7) or disagree (1) with a statement about how nutrient
loss impacts water quality in local streams, rivers and waterways. They could also select that
they did not know or were unsure how local streams, rivers and waterways were impacted (8)
or neutral (4).
A means analysis shows that overall land managers held a neutral view, they neither agree
nor disagree with the statement about the whether or not nutrient loss from their property has
an impact on local streams, rivers and waterways.
Table 23: Means analysis of the statement about how nutrient loss impacts Wet Tropics water quality
1st Round 3rd Round
n Mean SD n Mean SD
Nutrient loss from my property has no impact on water quality in local streams, rivers & waterways
246 4.90 2.21 69 4.86 2.23
Note: 1=strongly disagree, 7=strongly agree, *=significant at 5% level
A frequency analysis indicates that land managers in both first round (41.9%) and third round
(37.7%) data collection do not think that nutrient loss from their property has an impact on
water quality in local streams, rivers and waterways. By contrast 30% in both rounds do think
49
that nutrient loss has an impact. While 15% in each round of data collection remained neutral,
i.e. neither agreeing nor disagreeing, slightly more land managers in the third round did not
know or were not sure if nutrient loss from their property has an impact on water quality in local
streams, rivers and waterways.
Figure 3: Responses from Wet Tropics land managers about nutrient loss from their property impacting
local streams, rivers and waterways
When asked what Wet Tropics land managers thought was the top two causes of poor water
quality in local streams, rivers and waterways, first round responders offered, other farming as
the top most cause and urban development as the second top cause. In the third round of
data collection, the top cause identified by land managers was weather including natural run-
off from heavy rainfall and floods and the second top cause was farming. In particular, farming
was identified as banana, grazing, fruit growing, hobby farmers, cane farming and excess
nutrients, chemicals and pesticides that come from farming. In both rounds of data collection,
a small percentage of land managers commented that there was no poor water quality,
although the responses were less in the third round of data collection. Congruent with first
round data reporting (Farr, Eagle, Hay, & Churchill, 2017c), the data indicates that land
managers in the cane industry may be shifting the blame for the causes of poor water quality
to other farmers (bananas, grazing and fruit growing), industry, government and individuals.
Interestingly, very little blame is attributed to urban development, which is often cited by land
managers as the main cause of poor water quality in the GBR Basin, see Appendix 6.
0
10
20
30
40
50
Somewhat disagree,Disagree, Strongly
disagree
Neutral Somewhat agree, Agree,Strongly agree
Do not know/Not sure
Nutrient loss from my property has no impact on water quality in local streams, rivers & waterways
1st Round (n=246) 3rd Round (n=69)
50
Table 24: Wet Tropics land managers - Top causes of poor water quality in local streams, rivers and water ways
1st Round 3rd Round
Cause 1 Cause 2 Cause 1 Cause 2
n Percent n Percent n Percent n Percent
Farming (Banana, Cane, Grazing and Fruit Growing)
42 19.3 32 23.7 14 13.6 13 20.3
Feral Animals (Pigs) 37 17.0 17 12.6 19 18.4 7 10.9
Weather/Natural Run-off/Floods/Rainfall
33 15.1 17 12.6 29 28.2 14 21.9
Other Industry or Government
21 9.6 2 1.5 0 0.0 2 3.1
Blockages in creeks, clearing creeks and drains
19 8.7 10 7.4 6 5.8 6 9.4
Erosion 18 8.3 4 3.0 13 12.6 6 9.4
Illegal dumping/Accidental Spills/Pollution
15 6.9 2 1.5 0 0.0 0 0.0
No poor water quality 11 5.0 3 2.2 4 3.9 1 1.6
Bare ground 9 4.1 8 5.9 0 0.0 0 0.0
Cultivation Practices 4 1.8 11 8.1 3 2.9 2 3.1
Urban Development 3 1.4 24 17.8 9 8.7 9 14.1
Run-off 3 1.4 2 1.5 3 2.9 2 3.1
Construction/Civil Works 2 0.9 2 1.5 0 0.0 0 0.0
Climate Change/Global Warming
1 0.5 0 0.0 1 1.0 1 1.6
Don't know 0 0.0 1 0.7 2 1.9 1 1.6
Total 218 100 135 100 103 100 64 100
Next land managers were asked to strongly agree (7) or strongly disagree (1) with a statement
about the role that cane-growing plays in the declining health of the Great Barrier Reef (GBR).
Land managers could also select that they did not know or were unsure (8) or neutral (4) about
what role cane growing plays in the declining health of the GBR.
A means analysis indicates a neutral stance in the first round data and a somewhat agree
stance in third round data (see Table 25) about cane growing playing no role in the declining
health of the Great Barrier Reef.
Table 25: Means analysis of Wet Tropics land manager statement about the role cane growing plays in the
declining health of the Great Barrier Reef
1st Round 3rd Round
n Mean SD n Mean SD
Cane-growing plays almost no role in the declining health of the Great Barrier Reef
243 4.89 1.89 69 5.33 1.98
A frequency analysis of the same data shows a strong agreeance in both rounds of data
collection (see Figure 4), indicating that land managers in the Wet Tropics cane growing region
do not think that cane growing contributes to the declining health of the GBR.
51
Figure 4: Responses from Wet Tropics land managers about the role cane growing plays in the declining
health of the Great Barrier Reef
Participants were asked to write their comments about what they thought the two top pressures
were on the GBR. In the first round data, land managers listed climate change (natural cycles)
or global warming (rising sea temperatures) and weather (floods, natural run-off, heavy rainfall,
cyclones, lack of rainfall and extreme weather events) as the top pressures on the Great Barrier
Reef. This was followed by urban development, weather and climate change, which was listed
as the second top pressure on the health of the GBR in the first round of data collection. In
the third round, climate change and global warming were still listed as the top pressure along
with tourism, fishing and shipping (in that order).
The second top pressure listed by land managers in the third round of data collection was
weather, followed by urban development, then tourism, fishing and shipping (in that order).
Only a small percentage of land managers acknowledged that farming (cane, banana, grazing,
and fruit growing) added pressure to the health of the GBR. These results support earlier
findings (Farr et al., 2017c, pp. 64-65) that land managers tend to shift the blame related to
water quality and the health of the Great Barrier Reef to other organisations, industries and
individuals rather than consider their own practices as adding pressure to the GBR.
25.120.2
49.0
5.8
20.314.5
46.4
18.8
0
10
20
30
40
50
60
Somewhat disagree,Disagre, Strongly
disagree
Neutral Somewhat agree,Agree, Strongly agree
Do not know/Not sure
Perc
ent
Cane-growing plays almost no role in the declining health of the Great Barrier Reef
1st Round (n=243) 3rd Round (n=69)
52
Table 26: Wet Tropics land manager - two top pressures on the health of the Great Barrier Reef
1st Round 3rd Round
Pressure 1 Pressure 2 Pressure 1 Pressure 2 n Percent n Percent n Percent n Percent
Climate Change/Global Warming
72 32.4 25 12.8 38 36.9 6 6.5
Urban Development 43 19.4 40 20.5 9 8.7 18 19.4
Weather/Natural Run-off/Floods/Rainfall
38 17.1 36 18.5 15 14.6 22 23.7
Fishing/Shipping/Tourism 24 10.8 24 12.3 16 15.5 14 15.1
Acidification/CoT/Coral Bleaching
11 5.0 16 8.2 2 1.9 11 11.8
Farming (Banana, Cane, grazing and Fruit Growers)
10 4.5 12 6.2 1 1.0 3 3.2
Run-off 9 4.1 24 12.3 4 3.9 10 10.8
Erosion 3 1.4 2 1.0 0 0.0 0 0.0
Feral Animals (Pigs) 3 1.4 6 3.1 1 1.0 0 0.0
Other Industry or Government, Research
3 1.4 7 3.6 13 12.6 4 4.3
Cultivation Practices 2 0.9 0 0.0 0 0.0 0 0.0
Blockages in creeks, cleaning creeks and drains
1 0.5 0 0.0 1 1.0 1 1.1
No poor water quality 0 0.0 0 0.0 1 1.0 0 0.0
Illegal dumping/Accidental Spills/Pollution
0 0.0 1 0.5 2 1.9 4 4.3
Construction/Civil Works 0 0.0 1 0.5 0 0.0 0 0.0
Don't know 3 1.4 1 0.5 0 0.0 0 0.0
Total 222 100 195 100 103 100 93 100
6.3.1.7 Wet Tropics Cane Growers Results Summary
This section has reported on results from questions related to nutrient and run-off management
practices in the wet tropics region of Queensland, Australia.
The results from the analysis confirm that land managers in the wet tropics goals for their
property are to improve their land and remain productive and sustainable into the future. When
making decisions to reach their goals, land managers are driven by maintaining family
traditions and heritage and by maintaining good relations with other farmers in their local area.
While maintaining physical and mental health, spending time with the family and keeping in
contact with family and friends were important, they were not seen as influencers to decision
making.
Financially, land managers are influenced by maximising profits and servicing debt and they
are also influenced by having their efforts recognised by the wider community and sharing new
ideas with others. Both having efforts recognised and sharing new ideas have increased in
importance as influencers during the study. Likewise, minimising run-off and/or nutrient losses
has increased in importance as an influencer over the duration of the study. When thinking
about environmental influencers, safeguarding local waterways and the GBR were more
important than safeguarding native plants and animals, when making decisions on what to do
on the land manager’s property.
53
The data shows that when calculating fertiliser rates, the main practice is to tailor fertiliser rates
to different parts of the property. However, there has been a slight increase in participants that
are using industry standards over the duration of the study. This change may be due to an
increase in advisors calculating fertiliser rates for land managers in the final year of the study.
Advisors were identified as industry extension officers, private agronomists and researchers.
Land managers also rely on their own knowledge and that of best management practices as
well as fertiliser companies and resellers when calculating fertiliser application rates.
More than 60% of land managers nominated fertiliser resellers as their advisors, highlighting
fertiliser resellers as highly influential to land managers when making decisions about
calculating fertiliser rates. Anecdotal comments from land managers (and extension officers)
during the study period have confirmed this influence as a reason for not following best
management practice in fertiliser application. Several land managers (and extension officers)
have also stated that land managers will ignore best management practice if the reseller
incentivises fertiliser purchases e.g. buy two tonnes of fertiliser and get one tonne free.
When making decisions about fertiliser rates land managers are influenced by farmers they
respect and how they are calculating their fertiliser rates. The regions land managers survey
results indicate that other land managers had the technical knowledge and that they would be
able to afford to implement the systems used to calculate fertiliser rates. The way that land
managers calculate fertiliser rates was identified as the best way to meet their own personal
goal and that they selected the method they used because it was the least time consuming.
When comparing the same land managers who completed the survey in the first round and
again in the third round, the data showed that there has been a change in the way land
managers are calculating fertiliser application rates. More land managers are using industry
standard rates for district yield potential, calculating rates for high yielding blocks, using
advisors and using estimates from farm yield. While less land managers are using more
fertiliser on low yielding blocks that on other blocks. While the results indicate changes in the
way that land managers are calculating their fertiliser application rates, the results cannot
determine if land managers are using best practice management techniques to calculate
fertiliser rates or some other method. It should be noted that many of the repeat survey
respondents are most likely still engaged and value best management processes that have
supported them. By contrast, some of the growers who have not made changes may have
decided not to participate in the survey, which may affect the results of the survey.
Land managers highlighted industry extension and private agronomists as advisors whose
advice they follow most in both rounds of data collection. In first round the third most trusted
advisor was selected as ‘other’ and included advisors as their own experience, fertiliser
resellers, and best management practice, agronomists, financial constraints and agricultural
productivity boards. In third round, the third highest ranked advisor was researchers followed
by family who are also cane farmers. The least followed advice in first round was regional
cane associations and in third round was people from government departments. The data
indicates, while land managers followed advice from people from government departments
more in first round data collection (individually ranked third), they were not following their
advice in third round as evidenced by being ranked twelfth by land managers.
54
When handling run-off nearly one third of land managers are following conventional run-off
management practices such as using recycle pits and sediment traps and one third are not
capturing run-off. However, this may be a result of not using irrigation practices in the Wet
Tropics region.
Land managers are influenced to make their decisions about handling run-off by farmers they
respect, and by the people or organisations whose advice they follow most and think that they
should do the practice. The survey results indicate that the respondent land managers think
that other land managers have the technical knowledge to implement and that they would be
able to afford to implement the systems used to handle run-off. The surveyed land managers
identified that no one was forcing them to use the methods that they were using to handle run-
off. The way that land managers calculate fertiliser rates was identified as the best way to meet
their own personal goal, the most effective way of controlling nutrient loss from their property,
the best way to maintain good cash flow and the best way to reduce business risk. However,
the method being the least time consuming was highlighted as the main motivator for
calculating run-off.
The majority of land manager respondents identified that they were using other innovative
practices to manage nitrogen and/or run-off. When matching responses to the ABCD
Framework, it was identified that the practices being used met conventional to best
management practice expectations.
Overall the land managers surveyed neither agreed nor disagreed that nutrient losses from
their property have an impact on local streams, rivers and waterways. On closer inspection
the data shows that surveyed land managers think that nutrient loss from their property does
not have an impact on water quality in local streams, rivers and waterways. However, less
land managers felt this way at the end of the study. By contrast in both rounds of data
collection, nearly one third of participants did think that nutrient loss has an impact on water
quality. The remainder either did not know or remained neutral in their thoughts.
In the beginning of the survey period, land managers identified problems with water quality
being caused by other farmers, by the end of the study, they identified the weather (high
rainfall, natural run-off, floods, cyclones and extreme weather events) to be the top causes of
poor water quality. By contrast climate change and global warming were the least causes of
poor water quality in local streams, rivers and waterways.
Cane farmers in the Wet Tropics region indicated that cane growing does not contribute to the
declining health of the Great Barrier Reef. They identified the top pressure in the beginning of
the study to be climate change or global warming and urban development, in the final year of
the study land managers identified the pressure on the health of the Great Barrier Reef also to
be caused by climate change or global warming or other weather related events.
The Burdekin region survey was delivered by telephone to land managers using James Cook
University research staff. The data was directly entered into Qualtrics using the Survey
55
Software. Each telephone interview took approximately 40 minutes to complete. The data
imported to SPSS for analysis. For cane farming a total of 76 surveys were collected in 2018.
In 2016, 53 surveys were completed bringing the total number of surveys to 129. For grazing
a total of 105 surveys were collected in 2018. In 2016, 80 surveys were completed bringing
the total number of surveys to 185.
Data from the first round (2016) of the Burdekin survey was compared with the third round
(2018) Burdekin survey results to determine if there were any changes to behaviour or attitude
towards improving nutrient and run-off practices for improved water quality in the GBR Basin.
Below are the results from questions related to nutrient and run-off management practices,
results from structural equation modelling are presented in Section 6.3.4.
6.3.2.1 Factors that influence land manager decisions
To understand the factors that influence their decisions, land managers were asked to identify
the two most important things that they hoped to achieve for their farm or property.
Land managers comments were coded into themes using first round and third round data. In
the first round of the study, the main goal of land managers was to be productive and efficient
and their second goal focussed on improving farming practices for both profit and the
environment. In the third round of the study, land managers main goal had changed slightly
to remaining viable, having financial security and reducing debt and their second goal was then
focussed on improving productivity and farming practices. The responses indicate that
improving their land so that it can remain productive and sustainable into the future is important
to land managers, highlighting a motivation to participate in good farming practices.
Table 27: Burdekin sugar cane land manager’s personal goals to achieve on farm/property
1st Round 3rd Round
Goal 1 – Productivity/Efficiency Goal 1 – Viability/Financial Security
Production - produce the most you possibly can; most efficient production; better productivity, get more out of the land
To make a reasonable living and live comfortably; financially viable; retire in a good financial position; financial success
Goal 2 – Improving farming practices for profit and environment
Goal 2 - Productivity/Efficiency
Continually educate ourselves to be the best farmers we can be. Pass on this knowledge as we go to friends and family; to produce the best tonnes per sugar per HA while still providing environmental practices. it’s a balance of both and neither one should compromise each other; diversification into value adding products; keep improving the property, more efficient, make profit
Continuing to improve crop yields; maintain yields and reduce my inputs; make it a mantel piece for productivity; efficient farming
6.3.2.2 Decision making drivers
The next question asked land managers how important they thought a set of 21 statements
were when making decisions about what to do on their farm or property (See Table 28). The
participants were asked to choose the importance of each statement on a scale of 1-extremely
unimportant to 8 where 7 was equal to extremely important (essential) and 8 was equal to ‘I
don’t know’, the number 4 was listed as neutral. A means analysis was applied to compare
56
first and third round land manager responses. Followed by an independent samples t-test to
establish any significant difference in the responses.
Family, friends and other land manager influences
The first set of statements consider family, friends, health and other land manager influences
when making decisions. All of the statements were more important in the third round of data
collection than they were in the first round, except for ‘maintaining traditions and heritage’.
While ‘maintaining physical and mental health of family’ was selected as important to extremely
important, by contrast, land managers selected ‘maintaining traditions and heritage’ as being
less important, rating the statement between neutral and important when making decisions on
their farm or property. An independent t-test showed that none of the statements were
statistically different between data collection points.
Financial influencers
Similarly, all of the statements that considered financial influences (keeping farming cost low,
maximising profits, minimising risk, keeping a steady cash flow and servicing debt) were
indicated as important. However, in this case land managers rated them as less important to
consider when making decisions about what to do on the farm in the third round of data
collection compared to the first round data collection. Of least importance in third round data
when making decisions was ‘servicing debt’ indicating that other influencers were more
important. There was no statistical difference for decision influencers between data collection
points.
Land management influencers
The next set of statements consider land management influences when making decisions.
There is a statistical difference between first and third round data collection in one land
management statement. Land managers felt that ‘learning about and testing new ways of
doing things on their farm or property’ was more important in first round data (M=6.17;
SD=1.03) than in the third round (M=5.69, SD=1.33; t(91)=1.91, p=.05, two tailed) when
making decisions about what to do on their property. While the other statements were
identified as important, there was no statistical difference between statements over the data
collection points. ‘Being able to make their own decisions about their farm/property’ was the
most important in the first and third round of data collection. ‘Having efforts recognised by the
wider community’ was the least important consideration in both first and third round data
collection for land managers when making decisions about what to do on the Burdekin cane
farmers properties.
Farming practices
When considering how farming practices influence decisions, there was a statistical difference
between first round (M=6.59; SD=0.86) and third round (M=6.18, SD=1.05; t(91)=2.07, p=.04,
two tailed) data collection for ‘leaving the land/farm in better condition than it was when the
land manager got there’. While rated as important, the scores show that leaving the farm in
better condition is slightly less important in third round data collection than it was in first round
data collection. While maintaining or improving water supplies and storage and minimising
sediment run-off or nutrient losses were rated as important, there is no statistical difference
between land manager responses in the first round to the third round, indicating that these
factors are considered important to decisions about what to do on the land managers farm or
property.
57
Safeguarding local waterways, native plants and animals and the Great Barrier Reef
The final set of statements indicate that safeguarding local waterways, the Great Barrier Reef
(GBR) and native plants and animals are important to land managers. There is a statistical
difference between first round and third round data for all three statements about safeguarding
local waterways (first round M=6.36; SD=1.03 and third round (M=5.78, SD=1.29; t(91)=2.11,
p=.04, two tailed), native plants and animals (first round M=5.95; SD=1.38 and third round
(M=5.14, SD=1.52; t(91)=2.68, p=.00, two tailed) and the Great Barrier Reef (first round
M=6.40; SD=1.15 and third round (M=5.84, SD=1.27; t(91)=2.42, p=.01, two tailed). However,
while overall the level of importance that influences decisions about what to do on the land
managers farm or property has decreased between first and third year data collection, the
statements about safeguarding native plants and animals and helping to safeguard the GBR
are more significant than safeguarding local water ways.
Table 28: Burdekin sugar cane land manager responses decision making drivers
1st Round 3rd Round
n Mean SD n Mean SD
Maintaining physical and mental health of family 42 6.19 1.45 51 6.31 1.22
Spending face-to-face time with family and friends 42 5.79 1.57 51 6.06 1.03
Maintaining good relations with other farmers/graziers in the local area
42 5.43 1.50 51 5.43 1.25
Keeping in contact with family and friends in other ways (e.g. via phone, through social media)
42 5.31 1.55 51 5.45 1.53
Maintaining family traditions and heritage 42 5.05 1.94 51 4.78 1.87
Keeping farm costs low 42 6.43 1.13 51 6.31 1.22
Maximising farm profits (income minus costs) 42 6.43 1.17 51 6.31 1.05
Minimising risk (of very high costs or very low income) 42 6.40 1.01 51 6.18 1.14
Keeping a stable (steady) cash-flow 42 6.29 1.33 51 6.20 1.30
Servicing debt 42 6.14 1.37 51 5.82 1.35
Being able to make your own decisions about your farm/property
42 6.45 1.27 51 6.35 1.02
Learning about and testing new ways of doing things on your farm/property*
42 6.17 1.03 51 5.69 1.33
Sharing new ideas with others 42 5.64 1.41 51 5.10 1.60
Having time to pursue hobbies 42 5.26 1.52 51 4.78 1.69
Having efforts recognised by the wider community 42 4.57 1.82 51 4.08 1.80
Leaving the land/farm in better condition than it was when you first started managing it*
42 6.60 0.86 51 6.18 1.05
Maintaining/improving water supplies and storages 42 6.50 0.97 51 6.16 1.07
Minimising sediment run-off and/or nutrient losses 42 6.40 1.27 51 6.14 1.39
Helping to safeguard the Great Barrier Reef* 42 6.40 1.15 51 5.84 1.27
Helping to safeguard local waterways* 42 6.36 1.03 51 5.78 1.29
Helping to safeguard native plants and animals* 42 5.95 1.38 51 5.14 1.52
Note: 1=strongly disagree, 7=strongly agree, *=significant at 5% level
58
6.3.2.3 Irrigation Management Practices
Land managers were asked to answer a series of questions about their irrigation management
practices. The questions were asked to help the researchers to know the reasons why
Burdekin Cane Growers are doing specific agricultural practices and what motivates them to
make those decisions, as well as whose advice the land managers are following. The
responses from the first round of data were compared to responses from the third round of
data to identify any changes in irrigation management practices.
Irrigation practices
When asked if they use irrigation practices, 92.1% of land managers in the first round and
97.7% in the third round of data collection responded ‘Yes’. The amount of water used varied
from 2 mega litres (ML) to 20ML per hectare per year. Land managers added that it depended
on the soil type and on whether it was a dry or a wet year. In the first round of data collection
91.4% of land managers thought that between zero and 25% of irrigation water ran off the
block, the number was slightly less in the third round (88.1%). More land managers selected
that 25-50% of irrigation water runs off their block in third round (11.9%) data collection,
compared to the first round (8.6%).
Type of irrigation tools used
Land managers were asked what type of irrigation tools that they used. More land managers
are using soil moisture probes in the third round (30.4) of the study than in the first round
(24.2%). By contrast less selected mini pans (an in furrow irrigation system that relies on
evaporation to refill) as their irrigation tool of choice in the third round. Of the land managers
that selected other, more than 50% in each round of data collection wrote that they used
experience as their main tool for managing irrigation. In the third round 40% of those that
selected other are using g-dots (a new system that measures a kPa range to indicate when
irrigation is required, which helps to reduce both electricity consumption and run-off) as their
irrigation tool. When asked if they planned to use the same tools next year 93.9% in the first
round and 81.3% in the third round of data collection agreed that they would use the same
irrigation tools. Of those that were not going to use the same tools, they commented that they
would use electronic moisture testing, an automated system or a soil moisture meter.
59
Table 29: Type of irrigation tools used by Burdekin sugar cane land managers
1st Round 3rd Round
n Percent n Percent
Soil moisture probes such as tensiometers and capacitance probes (to identify water use and predict next irrigation)
16 24.2 18 30.4
Mini pans (in furrow-irrigated system based on evaporation) 15 22.7 5 8.9
Calculation of daily crop water use, using crop factors, class A pan, or crop model (e.g. WaterSense).
10 15.2 4 5.4
None 5 7.6 11 19.6
Other (please tell us which ones)* 20 30.3 20 35.7 66 100 56 100
*Other
Experience (gut feeling, experienced eye, rule of thumb, years of observation, scheduling)
11 55.0 10 50.0
Enviropans, trickle irrigation, run pumps, recycle pit 4 20.0 0 0.0
G-dots (a new type of tensiometer) 2 10.0 8 40.0
Leaf Stress, plant growth rate 2 10.0 0 0.0
Evaporation bucket calibrated to growth of cane 1 5.0 0 0.0
20 100 18 100
Advice land managers follow when scheduling irrigation?
Land managers were asked to rank from 1= most important to 12=least important whose
advice they follow most when scheduling irrigation. However, due to third round data being
collected via telephone interviews, the participants found it difficult to remember and rank 12
variables (see ** in Table 30). Therefore, participants were given the option to rank only the
top 5 advisors they follow when scheduling irrigation. A cross tabulation between ‘advice land
managers follow when scheduling irrigation’ and ‘round of data collection’ compared the top
five responses from the third round of data collection (see Table 30).
The first round results are not accurate due to a skip logic error in the first round data collection;
therefore the results are not reported here and no comparison can be made between first round
and third round.
In the third round data collection, the advisors ranked private agronomists as the top advisor,
followed by industry extension, family who are also cane farmers, others, and people from NQ
Dry Tropics. Other advisors were listed as using land managers own experience, farmers from
different industries, and extension officers from farm assist and government (see Table 30).
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Table 30: Advice Burdekin sugar cane land managers follow when considering irrigation, ranked 1 most important to 12 least important – 3rd Round data collection – top 5
Advisor 3rd Round
Rank 1 2 3 4 5 6 7 8 9 10 11 12 Total
Private Agronomists 10 1 3 2 0 0 0 0 0 0 0 0 16
Industry extension advisors (e.g. from SRA [BSES], Production Boards, Productivity Services group)
7 9 1 0 2 0 0 0 0 0 0 0 19
Family who are also cane farmers
4 1 3 2 0 1 0 0 0 0 0 1 12
Other. Who?* 4 1 0 0 1 1 0 0 1 1 0 0 9
People from NQ Dry Tropics
1 2 2 1 0 0 0 2 0 0 0 0 8
*Other. Who? (Number of responses): their own experience (4), farmers in different industries where irrigation is a lot more critical, such as small crops (1); extension officers from farmassist (1); Government Departments: DAFF/DERM (2), TNR (1)
**List of 12 advisors that land managers could choose from: Family who are also cane farmers; Other cane farmers; Private Agronomists; Researchers; Cane Growers (the organisation); Regional cane association (e.g. from Kalamia, Invicta, Inkerman, Tully Sugar); People from NQ Dry Tropics/TERRAIN; Other. Who?; Landcare; Industry extension advisors (e.g. from SRA [BSES], Production Boards, Productivity Services group); Other extension officers. From where?; People from government departments. Which departments?
While there was less focus on resellers and fertiliser companies as advisors in the Burdekin
region as compared to the Wet Tropics region, it is important to note the influence that networks
have on land manager decisions. These networks may be identified as either positive or
negative and may become enablers or barriers to practice change. The findings support
previous recommendations for a land manager network analysis to ensure that information
gatekeepers and opinion leaders influence future water quality communication strategies (see
Hay & Eagle, 2018).
Attitudes and motivations associated with current tools for scheduling irrigation
The next question asked participants how important they thought a set of listed statements
were to land managers when thinking about their current tools for scheduling irrigation. The
participants were asked to choose the importance of each statement on a scale of 1-strongly
disagree to 7 strongly agree, with 4 being neutral. There was also an option to select 8, I don’t
know or not sure.
The first set of statements considers land manager influencers when thinking about their
current tools for scheduling irrigation. The results indicate that land managers decisions about
scheduling irrigation are somewhat influenced by ‘the farmers I respect most do this’ in both
first round (M=5.83; SD=1.33) and third round (M=5.39; SD=1.81) data. Land managers
selected neutral to somewhat disagree, about whether or not ‘most farmers in the region would
have the technical knowledge to schedule irrigation’. They also somewhat disagreed that most
farmers would not be able to afford to use the system that they did for scheduling irrigation.
There was a significant change in the choice ‘I only do this because I am forced to’ (by BMP
accreditation, lack of money, state government or reducing labour, energy and water costs) in
third round (M=2.00; SD=1.61) compared to first round (M=3.83; SD=2.64). The results
61
indicate that land managers disagree that they are being forced to make decisions about their
current irrigation scheduling practices.
Table 31: Burdekin sugar cane land manager attitudes and motivations associated with scheduling irrigation
1st Round 3rd Round
n Mean SD n Mean SD
The farmers I respect most do this* 6 5.83 1.33 28 5.39 1.81
Most farmers in this region would not have the technical knowledge to do this
6 4.00 2.61 28 3.64 2.08
Most farmers in this region would not be able to afford to use this system for scheduling irrigation
6 4.83 3.19 28 3.64 2.13
I only do this because I am forced to. Who/what is forcing you?*
6 3.83 2.64 28 2.00 1.61
Note: 1=strongly disagree, 7=strongly agree, *=significant at 5% level
An independent t-test highlighted a significant difference for ‘the farmers I respect most do this’
scores for first round (M=5.83, SD=1.33) and third round (M=5.39, SD=1.81; t(32)=0.56, p=.05,
two tailed). The magnitude of difference in the means (mean difference =.44, 95% CI: -1.15
to 2.04) was small (eta squared =.01). The results indicate that while the farmers that land
managers respected most when scheduling irrigation increased in importance between first
round and third round data collection, only 1% of the variance was explain by time between
the data collection points.
The effect was opposite for the ‘I only do this because I am forced to’ factor. An independent
t-test highlighted a significant difference for ‘I only do this because I am forced to’ scores for
first round (M=3.83, SD=2.64) and third round (M=2.00, SD=1.61; t(32)=2.25, p=.03, two
tailed). The magnitude of difference in the means (mean difference =1.83, 95% CI: 0.17 to
3.49) was large (eta squared =.14). The results indicate that land managers are feeling less
forced to schedule their irrigation practices in the third round of the study compared to the first
year of the study and that 14% of the variance can be explain by time between the data
collection points. This may be influenced by new and affordable technologies that are available
to indicate when irrigation is required e.g. G-Dots. There was no significant difference between
the other means across the two data collection periods.
Land managers were next asked ‘compared to other ways of scheduling irrigation, what
motivates to you use the system that you use?’ While all statements have high agreement
(see Table 32) ‘the most effective way of controlling nutrient loss from my property’ (M=6.17,
SD=1.47) is the most significant motivator for using the scheduling tools that the land manager
is using.
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Table 32: Compared to other ways of scheduling irrigation, what motivates Burdekin sugar cane land managers to use the system that you use?
1st Round 3rd Round
n Mean SD n Mean SD
The most effective way of controlling nutrient loss from my property*
6 6.17 1.47 28 4.75 1.51
The best way to maintain good cash-flow 6 6.17 1.33 28 5.29 1.05
The best way to reduce business risk 6 6.17 1.33 28 5.29 1.21
The best way to meet my own personal goals 6 6.00 1.41 28 5.46 0.88
The least time-consuming (or labour intensive) 6 5.17 2.23 28 5.29 1.49
Note: 1=strongly disagree, 7=strongly agree, *=significant at 5% level
An independent t-test highlighted a significant difference for ‘the most effective way of
controlling nutrient loss from my property’ scores for first round (M=6.17, SD=1.47) and third
round (M=4.75, SD=1.51; t(32)=2.09, p=.04, two tailed). The magnitude of difference in the
means (mean difference =1.42, 95% CI: .04 to 2.79) was large (eta squared =.12). The results
indicate that land managers in the third round of the study compared to the first year of the
study, remain neutral or slightly disagree that the scheduling tools that they are using are the
most effective way of controlling nutrient loss from their property and that 12% of the variance
can be explain by time between the data collection points. The results may indicate a loss of
confidence in the current tools used for scheduling irrigation or an uncertainty in the new tools
being used, further investigation is required (see Table 32). There was no significant difference
between the other means across the two data collection periods.
Have irrigation management practices changed?
To establish whether there was a change in the tools that land managers use to manage
irrigation between first and third round data collection, a multiple response cross-tabulation
was performed (see Table 33). The land manager unique identification number was used to
identify growers in each round of data collection (1=Grower First Round and 3=Same Grower
Third Round). There were 29 growers who responded to the statements in first round and 32
who responded in the third round of data collection.
The data indicates that less land manages have reported using mini pans in the third round to
manage irrigation compared to the first round of data collection. More land managers are soil
moisture probes as their tool to manage irrigation. By contrast, there has been a large
reduction in those land managers who responded that are calculating daily crop water usage
to manage irrigation from 20% in first round to 7% in third round. However, there has been a
slight increase in land manager who are using ‘other’ tools, see Table 33 for examples. While
the data in Table 33 indicates changes in the tools that land managers are using to manage
irrigation, the results cannot determine if land managers are using best practice management
techniques for irrigation management or some other method.
63
Table 33: Comparison between 'How first and third round Burdekin sugar cane land managers manage irrigation’
Have the tools that land managers use to manage irrigation changed?
Have you completed this survey before?
Grower 1st Round
Same Grower 3rd Round
Total
Mini pans Count 17 3 20
% within $IrrigTools 85.0% 15.0% % within CompBefore 28.3% 21.4% % of Total 23.0% 4.1% 27.0%
Soil moisture probes such as tensiometers and capacitance probes
Count 24 7 31
% within $IrrigTools 77.4% 22.6% % within CompBefore 40.0% 50.0% % of Total 32.4% 9.5% 41.9%
Calculation of daily crop water use, using crop factors, class A pan, or crop model (e. g. WaterSense).
Count 12 1 13
% within $IrrigTools 92.3% 7.7% % within CompBefore 20.0% 7.1% % of Total 16.2% 1.4% 17.6%
Other (includes: experience, enviropans, trickle irrigation, pumps, G-dots, leaf stress, evaporation bucket, automated irrigation)
Count 29 8 37
% within $IrrigTools 78.4% 21.6% % within CompBefore 48.3% 57.1%
% of Total 39.2% 10.8% 50.0%
Total Count 60 14 74
% of Total 81.1% 18.9% 100.0%
Percentages and totals are based on responses. a. Dichotomy group tabulated at value 1.
6.3.2.4 Nutrient Management Practices
Land managers were asked to answer a series of questions about their nutrient management
practices. The responses from the first round of data were compared to responses from the
third round of data to identify any changes in nutrient management practices.
Calculating fertiliser application rates
When asked how land managers calculate their fertiliser application rates, the 32.8% of land
managers in first round data collection and 29.4% in third round selected that they tailor their
fertiliser rates to different parts of the property. Twenty percent in both first and third round
data collection selected that their advisor calculates their fertiliser application rate for them.
More land managers in third round than in first round chose ‘Other’ as their chosen method to
calculate fertiliser application rates. Less land managers were using industry standards in the
third round of the study than in the first round. Other methods for calculating fertiliser
application rates include decisions based on soil tests, best management practice, depends
on other factors, use the same for everything and advice from industry representatives or
agronomists (see Table 34).
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Table 34: Burdekin sugar cane land manager responses to the question 'How do you calculate fertiliser application rates?"
1st Round 3rd Round
n Percent n Percent
I tailor my fertiliser rates to different parts of the property 19 32.8 20 29.4
My advisor does this for me (farm assist, biological consultant) 12 20.7 14 20.6
Other. Please tell us what you do* 9 15.5 17 25.0
I use industry standard rates for district yield potential, and use that amount on all parts of my farm
8 13.8 8 11.8
I estimate amounts from my farm yield and use that amount on all parts of my farm
4 6.9 4 5.9
I use more fertiliser on high – performing (high yielding) blocks 3 5.2 2 2.9
I use more fertiliser on under-performing (low yield) blocks than on other blocks
3 5.2 3 4.4
Total 58 100 68 100
Other. Please tell us what you do*
Decision based on soil tests 4 50.0 7 41.2
Best Management Practice (6 easy steps) 2 25.0 4 23.5
Depends on cash flow, ground water, experience, budget 1 12.5 3 17.6
I put the same amount on everything 1 12.5 0 0.0
Advice from agronomist, industry representative 0 0.0 3 17.6
Total 8 100 17 100
Advice land managers follow most when calculating fertiliser application rates
Land managers were asked to rank from 1= most important to 12=least important whose
advice they follow most when calculating fertiliser application rates. A cross tabulation between
‘advice land managers follow when calculating fertiliser rates’ and ‘round of data collection’
compared responses from the first and third rounds of data collection (see Table 35 and Table
36).
In the first round of data collection land managers sought advice from private agronomists,
industry extension and others for example their own experience, fertiliser companies and
resellers, and through trial results. Other extension included Farm Assist and SRA and
government agencies included DERM and EHP.
65
Table 35: Advice sugar cane land managers from the Burdekin follow when calculating fertiliser rates, ranked 1 most important to 12 least important – 1st Round data collection
Advisor 1st Round
Rank 1 2 3 4 5 6 7 8 9 10 11 12 Total
Private Agronomists 17 5 4 3 0 0 0 0 0 0 0 0 29
Industry extension advisors (e.g. from SRA [BSES], Production Boards, Productivity Services group) 8 9 2 1 0 1 0 0 1 0 0 0 22
Other. Who?* 4 2 0 1 0 0 0 2 1 0 1 0 11
Researchers 4 1 3 2 1 4 0 1 0 0 0 0 16
Family who are also cane farmers 2 4 1 4 3 0 1 0 0 0 2 0 17
Other extension officers. From where?** 2 1 1 1 0 0 2 0 0 1 0 0 8
People from NQ Dry Tropics/TERRAIN 1 1 2 3 0 0 3 2 1 0 0 0 13
Landcare 0 0 1 1 1 0 0 1 2 3 0 1 10
Regional cane association (e.g. from Kalamia, Invicta, Inkerman, Tully Sugar) 0 1 0 0 1 2 1 2 3 1 1 0 12
Other cane farmers 0 1 5 1 3 3 0 0 0 1 0 0 14
Cane Growers (the organisation) 0 0 1 0 2 1 3 1 2 1 0 0 11
People from government departments. Which departments?*** 0 0 1 0 0 0 1 1 0 1 2 2 8
*Other. Who? (Number of responses): their own experience (1), fertiliser companies and resellers (1), from local agronomists (3) and through trial results (1) **Other Extension, from where: Farm Assist (2), SRA (1). *** Government Departments: DERM (1), EHP (1)
In the third round of data collection private agronomists were still the first call for advice,
followed by industry extension and others including their own experience, fertiliser companies
and resellers, best management practice and local agronomists. One land manager indicated
that they had “been doing it so long that they did not need advice”. Other extension was from
Farm Assist and government agencies included DAF in the third round of data collection.
66
Table 36: Advice sugar cane land managers from the Burdekin follow when calculating fertiliser rates, ranked 1 most important to 12 least important – 3rd Round data collection
Advisor 3rd Round
Rank 1 2 3 4 5 6 7 8 9 10 11 12 Total
Private Agronomists 14 5 1 1 2 0 0 1 0 0 1 0 25
Industry extension advisors (e.g. from SRA [BSES], Production Boards, Productivity Services group) 10 13 2 1 0 0 1 2 0 0 0 0 29
Other. Who?* 10 1 0 0 1 0 0 0 0 1 0 2 15
Other extension officers. From where?** 3 2 1 1 1 0 0 0 0 3 2 0 13
Researchers 2 1 2 1 0 2 0 1 3 1 0 0 13
Regional cane association (e.g. from Kalamia, Invicta, Inkerman, Tully Sugar) 1 0 1 0 2 0 3 0 1 1 0 0 9
Landcare 1 1 0 0 0 0 1 2 2 1 0 1 9
Family who are also cane farmers 0 1 8 3 2 2 0 0 0 0 0 1 17
People from NQ Dry Tropics/TERRAIN 0 2 0 1 1 1 1 2 2 0 0 0 10
People from government departments. Which departments?*** 0 0 1 1 0 1 1 0 0 0 2 3 9
Cane Growers (the organisation) 0 2 0 2 0 1 1 1 0 1 2 0 10
Other cane farmers 0 4 9 3 1 2 1 0 0 0 1 0 21
*Other. Who? (Number of responses): their own experience (6), fertiliser companies and resellers (1), best management practice (1), from local agronomists (2) and no advice needed (1) **Other Extension, from where: Farm Assist (1). *** Government Departments: DAF (1)
Attitudes and motivations associated with calculating fertiliser application rates
The next question asked participants how important they thought a set of listed statements
were to land managers when making decisions about calculating fertiliser rates. The
participants were asked to choose the importance of each statement on a scale of 1-strongly
disagree to 7 strongly agree, with 4 being neutral.
The first set of statements considered influencers when making decisions about calculating
fertiliser rates. The data indicates that land managers decisions are somewhat influenced by
‘farmers they respect’ with regard to fertiliser rate calculations in both first (M=5.16, SD=2.03)
and third round (M=5.02, SD=1.79) data. Similarly, land managers are somewhat influenced
by ‘the people or organisations whose advice they follow most and think that they should do
this’ in first round (M=5.11; SD=1.93) and third round (M=5.09; SD=1.64). Land managers
somewhat disagreed with the last three statements indicating that other land managers would
able to afford to use the same systems to calculate fertiliser rates, they would have the
technical skills and that they are not being forced to calculate fertilise applications rates by
anyone. There were no significant difference in scores for each of the statements.
67
Table 37: Burdekin sugar cane land manager attitudes and motivations associated with calculating fertiliser application rates
1st Round 3rd Round
n Mean SD n Mean SD
The farmers I respect most do this 38 5.16 2.03 43 5.02 1.79
The people/organisations whose advice I follow most think I should do this 38 5.11 1.93 43 5.09 1.64
Most farmers in this region would not be able to afford to use this system for scheduling irrigation 38 3.82 2.13 43 3.26 2.09
Most farmers in this region would not have the technical knowledge to do this 38 3.74 2.16 43 3.65 2.22
I only do this because I am forced to. Who/what is forcing you? 38 3.26 2.08 43 2.47 2.15
Note: 1=strongly disagree, 7=strongly agree, *=significant at 5% level
The second set of statements ask the land manager to read the statement and respond how
using their method for calculating fertiliser rates measures when compared to other ways of
calculating fertiliser rates.
The data indicates that there is less agreement with the statements in the third round of data
collection than in the first round (see Table 38). The current system the land manager uses
being ‘the most effective way of controlling nutrient loss from my property’ is highlighted as
significant by an independent t-test for first round (M=6.05; SD=.98) and third round (M=5.35;
SD=1.62; t(79)=2.33, p=.02, two tailed) scores. The magnitude of difference in the means
(mean difference =.70, 95% CI: .11 to 1.29) was moderate (eta squared =.07) indicating that
‘the most effective way of controlling nutrient loss from their property’ had increased in
importance between first round and third round data collection, and that 6% of the variance
was explain by time between the data collection points.
Table 38: Compared to other ways of calculating fertiliser rates, what motivates Burdekin sugar cane land
managers to use the system that they use?
1st Round 3rd Round
n Mean SD n Mean SD
The most effective way of controlling nutrient loss from my property*
38 6.05 0.98 43 5.35 1.62
The best way to maintain good cash-flow 38 6.05 0.96 43 5.65 1.48
The best way to meet my own personal goals 38 5.82 1.23 43 5.70 1.41
The best way to reduce business risk 38 5.79 1.19 43 5.95 0.95
The least time-consuming (or labour intensive) 38 4.29 1.96 43 4.72 1.86
Note: 1=strongly disagree, 7=strongly agree, *=significant at 5% level
Has calculating fertiliser application rates changed?
To establish whether there was a change in the way land managers calculate fertiliser
application rates between first and third round data collection, a multiple response cross-
tabulation was performed (see Table 39). The land manager unique identification number was
used to identify growers in each round of data collection (1=Grower First Round and 3=Same
Grower Third Round). There were 55 growers who responded to the statements in first round
and 13 who responded in the third round of data collection.
68
Results in Table 39 indicate that there has been a change in the way land managers calculate
fertiliser application rates. While, none of the land managers who responded in the first round
to the statement ‘I use more fertiliser of high performing blocks’ responded in the third round,
more third round (15.4%) land managers are estimating amounts of fertiliser from their farm
yield and then using that on all parts of their farm compared to first round land managers
(9.1%). About the same number of land managers are using their advisor to calculate their
fertiliser application rate in both first (38.2%) and third (38.5%) rounds of data collection.
Similarly, slightly more land managers in first round (65.4%) compared to third round (61.5%)
are tailoring their fertiliser rates to different parts of their property. Of concern is that 10% less
land managers are using industry standard rates for district yield potential in third (15.4%)
round compared to first (25.5%) round data collection?
Table 39: Burdekin sugar cane land manager comparison between 'How first and third round land
managers calculate fertiliser application rates’
How do you calculate fertiliser application rates? Have you completed this survey before?
Grower 1st Round
Same Grower 3rd Round
Total
I use more fertiliser on high – performing (high yielding) blocks
Count 5 0 5
% within $FAPP 100.0% 0.0%
% within CompBefore 9.1% 0.0%
% of Total 7.4% 0.0% 7.4%
I estimate amounts from my farm yield and use that amount on all parts of my farm
Count 5 2 7
% within $FAPP 71.4% 28.6%
% within CompBefore 9.1% 15.4%
% of Total 7.4% 2.9% 10.3%
My advisor does this for me
Count 21 5 26
% within $FAPP 80.8% 19.2%
% within CompBefore 38.2% 38.5%
% of Total 30.9% 7.4% 38.2%
I use more fertiliser on under-performing (low yield) blocks than on other blocks
Count 3 0 3
% within $FAPP 100.0% 0.0%
% within CompBefore 5.5% 0.0%
% of Total 4.4% 0.0% 4.4%
I tailor my fertiliser rates to different parts of the property
Count 31 8 39
% within $FAPP 79.5% 20.5%
% within CompBefore 56.4% 61.5%
% of Total 45.6% 11.8% 57.4%
I use industry standard rates for district yield potential, and use that amount on all parts of my farm
Count 14 2 16
% within $FAPP 87.5% 12.5%
% within CompBefore 25.5% 15.4%
% of Total 20.6% 2.9% 23.5%
Total
Count 55 13 68
% of Total 80.9% 19.1% 100%
Percentages and totals are based on responses. a. Dichotomy group tabulated at value 1.
69
While the data in Table 39 indicates changes in the way that land managers are calculating
their fertiliser application rates, the results cannot determine if land managers are using best
practice management techniques to calculate fertiliser rates or some other method. In addition,
the sample is very small and therefore not representative of the entire Burdekin region.
6.3.2.5 Run-off Management Practices
Land managers were asked to answer a series of questions about their run-off management
practices. The responses from the first round of data were compared to responses from the
third round of data to identify any changes in run-off management practices.
Handling run-off
A multiple response analysis indicates that in first round one third (33.9%) of land managers
were following conventional run-off management practices such as using recycle pits and
sediment traps and 42% were following the same practices in third round. Another 30.5% were
using recycling pits with adequate pumping capacity to recycle the water in the first round of
data collection. This had decreased to 19.2% in the third round. Fifteen percent of land
managers were not capturing run-off in third round, which is indicative of the Burdekin region
that has less rainfall than the Wet Tropics region. Other practices in first round (30.5%), see
Table 40, were either meeting minimum expectations or were current practices as promoted
by the industry (ABCD Framework, Drewry et al., 2008; Trendell, 2013). By contrast this has
also decreased in third round data collection to 23.1%.
Table 40: Burdekin sugar cane land manager responses to the question 'how do you handle run-off from
rainfall or irrigation?’
ABCD Framework
1st Round 3rd Round
n Percent n Percent
I have recycle pits C 20 33.9 22 42.3
I have recycle pits and have adequate pumping capacity to recycle the water
B 18 30.5 10 19.2
I do not capture run-off D 3 5.1 8 15.4
Other. Please tell us what you do C-B 18 30.5 12 23.1
Total 59 100 52 100 ABCD
Framework 1st Round 3rd Round
Other* n Percent n Percent
Recycle pit/Sediment trap C 3 18.8 4 33.3
Grass and Drains C-B 3 18.8 1 8.3
Buffer Zones (end banks)/Riparian Boundary/Revegetation C-B
3 18.8 4 33.3
Contouring C-B 3 18.8 1 8.3
Laser levelled, silt trap, grass C-B 1 6.3 0 0.0
Natural drainage filter C-B 3 18.8 2 16.7
Total 16 100 12 100
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Advice land managers follow most when handling run-off
Land managers were asked to rank from 1= most important to 12=least important whose
advice they follow most when handling run-off. A cross tabulation between ‘advice land
managers follow when handling run-off’ and ‘round of data collection’ compared responses
from the first and third rounds of data collection (see Table 41 and Table 42).
Land managers in the first round sought advice from private agronomists, NRMs and industry
extension when handling run-off. In the first round of data collection the advice followed least
comes from people from government departments. While the question asked which
departments, none were listed by land managers.
Table 41: Advice Burdekin sugar cane land managers follow when handling run-off, ranked 1 most
important to 12 least important – 1st Round Data Collection
Advisor 1st Round
Rank 1 2 3 4 5 6 7 8 9 10 11 12 Total
Private Agronomists 10 6 1 1 1 1 1 1 0 0 0 0 22
People from NQ Dry Tropics/TERRAIN
3 4 2 3 2 0 2 1 0 0 0 0 17
Industry extension advisors (e.g. from SRA [BSES], Production Boards, Productivity Services group)
5 7 3 0 0 1 1 0 0 0 0 0 17
Other cane farmers 2 2 3 1 0 3 1 1 0 2 0 0 15
Researchers 4 0 2 2 2 0 0 2 3 0 0 0 15
Other. Who?* 7 2 0 1 0 0 1 1 0 1 1 0 14
Family who are also cane farmers
3 1 0 2 3 0 2 0 0 0 1 0 12
Cane Growers (the organisation)
1 0 1 2 3 2 0 0 2 0 1 0 12
Landcare 0 0 2 0 1 2 0 3 2 0 0 1 11
Other extension officers. From where?**
1 1 5 1 0 0 0 0 0 1 2 0 11
Regional cane association (e.g. from Kalamia, Invicta, Inkerman, Tully Sugar)
0 0 1 1 1 3 2 2 0 0 0 0 10
People from government departments. Which departments?
0 1 0 1 0 0 0 0 0 3 2 2 9
*Own research/knowledge (5), BBIFMAC - very helpful, practical advice rather than scientific (2), Reef Rescue (1), Researchers - you were the innovator, others come to you (1) **Catalyst Program (1), Farmacist (2), PSG (1)
In the third round data collection, land managers sought advice from industry extension, other
cane farmers and others including using their own research, NRMs, the Burdekin Productivity
Services, and Landcare, with one land manager highlighting that they are unable to finance
handling run-off so they do not seek advice, see Table 42.
71
Table 42: Advice Burdekin sugar cane land managers follow when handling run-off, ranked 1 most important to 12 least important – 3rd Round Data Collection
Advisor 3rd Round
Rank 1 2 3 4 5 6 7 8 9 10 11 12 Total
Industry extension advisors (e.g. from SRA [BSES], Production Boards, Productivity Services group)
9 4 3 1 0 2 0 0 0 1 1 0 21
Other cane farmers 4 7 3 1 1 1 0 0 1 1 1 0 20
Other. Who?* 9 2 0 0 1 1 0 1 0 0 0 2 16
Private Agronomists 4 5 4 0 0 1 0 0 1 0 0 0 15
Family who are also cane farmers
2 4 2 2 2 0 0 0 1 0 0 1 14
People from NQ Dry Tropics/TERRAIN
6 2 2 1 0 0 2 1 0 0 0 0 14
Cane Growers (the organisation)
1 0 2 2 1 0 1 1 0 1 2 0 11
Researchers 4 0 1 2 0 2 0 0 2 0 0 0 11
Other extension officers. From where?**
1 0 3 1 3 1 1 0 10
Landcare 1 4 1 0 0 1 1 0 0 0 1 0 9
Regional cane association (e.g. from Kalamia, Invicta, Inkerman, Tully Sugar)
0 2 0 1 0 0 1 2 1 0 0 1 8
People from government departments. Which departments?***
0 0 1 1 0 1 0 1 0 1 1 1 7
*Own research/knowledge (5), Because of the low lying nature of both my properties my options for change are limited and expensive so advice isn’t relevant if grant money was available I may talk to Nq dry topics (1), Burdekin Productivity Services (1), No one, unable to finance any other option, Landcare - used their system for 25 years, no new system needed (1), We are acutely aware of the implications of our run-off and try to keep it to a minimum but understand that a closed-loop recycle system or automated irrigation could reduce run-off. Doing all of this for a low value crop is unviable in the area we farm (1). **Farmacist (2) ***DAF (1)
Attitudes and motivations associated with handling run-off
The next question asked participants how important they thought a set of listed statements
were to land managers when making decisions about handling run-off. The participants were
asked to choose the importance of each statement on a scale of 1-strongly disagree to 7
strongly agree, with 4 being neutral.
The first set of statements considered decision influencers when using their current system for
handling run-off. The data indicates that land managers decisions were somewhat influenced
by ‘farmers who they respect most’ in the first round (M=5.05; SD=1.96), but more neutrally
influenced by respected farmers in the third round (M=4.95; SD=1.96). Although the
independent t-test shows that there is no statistical difference for each statement between the
rounds of data collection (see Table 43). The data indicates that land managers were more
72
certain in third round (M=5.36; SD=1.72) than they were in the first round (M=4.84; SD=1.90)
that they followed the advice of people or organisations whose advice they think they should
follow. Given that land managers indicated that their primary advisor is either a private
agronomist or an industry extension officer (see Table 35 and Table 36), this may indicate a
stronger compliance with best management practice. However, this will depend on if the
private agronomist and/or the industry extension officer is following best practice management
or not.
In both rounds of data collection land managers were neutral about statements surrounding
not being able to afford to use the recommended system and that other farmers would not
have the technical knowledge to handle run-off. By contrast, in both rounds of data collection,
land managers disagreed that anyone was forcing them to use their current system for handling
run-off, see Table 43. There were no significant difference in scores for each statement.
Table 43: Burdekin sugar cane land manager attitudes and motivations associated with calculating
fertiliser application rates
1st Round 3rd Round
n Mean SD n Mean SD
The farmers I respect most do this 38 5.05 1.96 42 4.95 1.96
The people/organisations whose advice I follow most think I should do this
38 4.84 1.90 42 5.36 1.72
Most farmers in this region would not be able to afford to use this system for handling run-off
38 4.18 2.12 42 4.64 2.30
Most farmers in this region would not have the technical knowledge to do this
38 3.08 1.87 42 3.50 2.20
I only do this because I am forced to. Who/what is forcing you?
38 2.97 2.12 42 2.86 2.18
Note: 1=strongly disagree, 7=strongly agree, *=significant at 5% level
The second set of statements ask the land manager to read the statement and respond how using
their method for handling run-off measures when compared to other ways of handling run-off.
All of the statements have a high agreeance except for the way that the land manager currently
handles run-off being ‘the least time consuming’. It is interesting to note that in the first round of
data collection land managers were more neutral (M=4.95, SD=1.90) about their way of handling
run-off being ‘the least time consuming’ than in the third round (M=5.19, SD=1.88) of data
collection.
Table 44: Compared to other ways of handling run-off, what motivates sugar cane land managers in the
Burdekin to use the system that you use?
1st Round 3rd Round
n Mean SD n Mean SD
The most effective way of controlling nutrient loss from my property*
38 6.32 0.90 42 5.69 1.65
The best way to meet my own personal goals 38 6.08 1.42 42 5.60 1.64
The best way to maintain good cash-flow 38 5.95 1.33 42 5.60 1.71
The best way to reduce business risk 38 5.79 1.44 42 5.40 1.65
The least time-consuming (or labour intensive) 38 4.95 1.90 42 5.19 1.88
Note: 1=strongly disagree, 7=strongly agree, *=significant at 5% level
73
An independent t-test highlighted a significant difference for ‘the most effective way of
controlling nutrient loss from my property’ scores for first round (M=6.32, SD=0.90) and third
round (M=5.69, SD=1.65; t(78)=2.07, p=.04, two tailed). The magnitude of difference in the
means (mean difference =.30, 95% CI: .01 to .61) was small (eta squared =.02). The result
indicates that while ‘the most effective way of controlling nutrient loss from my property’ had
decreased in importance between first round and third round data collection, only 1% of the
variance was explain by time between the data collection points. There was no significant
difference between the other means across the two data collection periods.
Has handling run-off changed?
To establish whether there was a change in the tools that land managers use to handle run-
off from rainfall or irrigation between first and third round data collection, a multiple response
cross-tabulation was performed (see Table 45). The land manager unique identification
number was used to identify growers in each round of data collection (1=Grower First Round
and 3=Same Grower Third Round). There were 62 growers who responded to the statements
in first round and 14 who responded in the third round of data collection.
There was a slight increase in land managers using recycle pits between first and third round
data collection. While 70% of land managers were not capturing run-off in the first round, only
30% of land managers reported not capturing run-off in the third round of data collection. Less
land managers (21.4%) reported that they had recycle pits with adequate pumping in the third
round of data collection than in the first round (38.7%). About the same amount of land
managers reported that they were doing something else to handle run-off in both rounds of the
study. See Table 45 for examples of other ways that land managers are handling run-off.
While the data in Table 45 indicates changes in the way that land managers are handling run-
off, the results cannot determine if land managers are using best practice management
techniques to handle run-off or some other method.
74
Table 45: Comparison between 'How first and third round Burdekin sugar cane land managers handle run-off from rainfall or irrigation’
Has the way land managers handle run-off from rainfall or irrigation changed?
Have you completed this survey before?
Grower 1st Round
Same Grower 3rd Round
Total
I have recycle pits Count 32 9 41
% within $Run-off 78.0% 22.0%
% within CompBefore 51.6% 64.3%
% of Total 42.1% 11.8% 53.9%
I do not capture run-off Count 7 3 10
% within $Run-off 70.0% 30.0%
% within CompBefore 11.3% 21.4%
% of Total 9.2% 3.9% 13.2%
I have recycle pits and have adequate pumping capacity to recycle the water
Count 24 3 27
% within $Run-off 88.9% 11.1%
% within CompBefore 38.7% 21.4%
% of Total 31.6% 3.9% 35.5%
Other (includes sediment traps, grass and drains, buffer zones, contouring, laser levelling with silt trap, natural drainage filter)
Count 24 5 29
% within $Run-off 82.8% 17.2%
% within CompBefore 38.7% 35.7%
% of Total 31.6% 6.6% 38.2%
Total Count 62 14 76
% of Total 81.6% 18.4% 100.0%
Percentages and totals are based on responses. a. Dichotomy group tabulated at value 1.
Other Innovative Run-off Practices
Land managers were asked if they used any other innovative practices to manage nitrogen
and/or run-off. Nearly 58% of land managers selected ‘yes’ that they thought they were using
innovative practices in first round data collection and 40.5% selected yes in the third round.
The land managers were asked to write down the innovative practices that they were using.
The responses were coded and matched to the ABCD Framework, see Table 46 for coded
responses. When matching responses to the ABCD Framework, most of the practices that
land managers noted met best management to aspirational practice expectations. A list of
anecdotal comments written by land managers describing the innovative practices they use
are included in Appendix 4.
75
Table 46: Other innovative practices used by Burdekin sugar cane land managers - anecdotal comments coded (see Appendix 4 for examples)
6.3.2.6 Perceptions of Causes and Pressure on Water Quality
Land managers were asked to agree (7) or disagree (1) with a statement about how nutrient
loss impacts water quality in local streams, rivers and waterways. They could also select that
they did not know or were unsure how local streams, rivers and waterways were impacted (8)
or neutral (4).
A means analysis shows that overall land managers held a neutral view to the statement about
whether or not nutrient loss from their property has an impact on local streams, rivers and
waterways.
Table 47: Means analysis of Burdekin sugar cane land managers to the statement about how nutrient loss
impacts water quality from the Burdekin region
1st Round 3rd Round
n Mean SD n Mean SD
Nutrient loss from my property has no impact on water quality in local streams, rivers & waterways
38 4.82 1.96 42 4.52 2.31
Note: 1=strongly disagree, 7=strongly agree, *=significant at 5% level
A frequency analysis indicates that land manager’s attitude towards nutrient loss from their
property having no impact on water quality in local streams, rivers and waterways has changed
over time. Less land managers agreed with the statement in the third round (38.1%) of the
study when compared to the first round (63.2%), indicating that they do recognise that nutrient
loss is having an impact on water quality in local streams, rivers and waterways. However, the
number of responses to ‘neutral’ and ‘don’t know/not sure’ have also increased, indicating
uncertainty amongst land managers.
1st Round 3rd Round
n Percent n Percent
Yes 22 57.9 17 40.5
No 16 42.1 25 59.5
Total 38 100 42 100
Coded Responses to Innovative Practices (see examples in Appendix 4)
ABCD Framework
1st Round 3rd Round
n Percent n Percent
Fertiliser/Bio Fertiliser
B - A
5 25.0 3 21.4
Alternative Crops/Irrigation 3 15.0 4 28.6
Headlands/Drains/Recycle Pits 0 0.0 2 14.3
Stool Splitting/Mixed Method 6 30.0 1 7.1
Best Management Practices 2 10.0 1 7.1
Applied Humates 2 10.0 1 7.1
Automated Flood System 1 5.0 1 7.1
1 5.0 1 7.1
20 100 14 100
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Figure 5: Responses from Burdekin sugar cane land managers about nutrient loss from their property
impacting local streams, rivers and waterways
When asked what Burdekin land managers thought were the top two causes of poor water
quality in local streams, rivers and waterways, they responded that the top cause was farming,
in both first round (37.1%) and third round (30%) data collection. The second top cause in first
round data was listed as weeds (59.3%) and in third round data the second top cause was
listed also as farming (26.3%). Interestingly, in third round data collection, salinity was
nominated as a top cause of poor water quality in local streams, rivers and waterways. In
particular, farming was identified as banana, grazing, fruit growing, hobby farmers, cane
farming and excess nutrients, chemicals and pesticides that come from farming. In both rounds
of data collection, a small percentage of land managers commented that there was no poor
water quality in the first round data collection, but not in the third round of data collection.
Congruent with first round data reporting (Farr et al., 2017c), the data indicates that land
managers in Burdekin cane industry may be shifting the blame for the causes of poor water
quality to other farmers. Interestingly, very little blame is attributed to urban development,
which is often cited by land managers as the main cause of poor water quality in the GBR
Basin, see Appendix 8 for anecdotal land manager comments, which were coded into themes.
23.7
10.5
63.2
2.6
35.7
19.0
38.1
7.1
0
10
20
30
40
50
60
70
Strongly disagree,disagree, somewhat
disagree
Neutral Somewhat agree, agree,strongly agree
Do not know/Not sure
Perc
ent
Nutrient loss from my property has no impact on water quality in local streams, rivers & waterways
1st Round (n=38) 3rd Round (n=42)
77
Table 48: Two top causes of poor water quality in local streams, rivers and water ways – Burdekin
1st Round 3rd Round
Cause 1 Cause 2 Cause 1 Cause 2 n Percent n Percent n Percent n Percent
Farming (Banana, Cane, Grazing and Fruit Growing)
13 37.1 5 18.5 12 30.0 5 26.3
Run-off 7 20.0 2 7.4 4 10.0 1 5.3
Weather/Natural Run-off/Floods/Rainfall
3 8.6 2 7.4 5 12.5 3 15.8
No poor water quality 3 8.6 0 0.0 2 5.0 0 0.0
Weeds 3 8.6 16 59.3 7 17.5 2 10.5
Urban Development 2 5.7 1 3.7 0 0.0 1 5.3
Feral Animals (Pigs) 1 2.9 0 0.0 0 0.0 0 0.0
Other Industry or Government 1 2.9 1 3.7 0 0.0 1 5.3
Blockages in creeks, clearing creeks and drains
0 0.0 0 0.0 0 0.0 2 10.5
Erosion 0 0.0 0 0.0 1 2.5 0 0.0
Bare ground 0 0.0 0 0.0 0 0.0 1 5.3
Salinity/Calcium 0 0.0 0 0.0 8 20.0 1 5.3
Don't know 2 5.7 0 0.0 1 2.5 2 10.5
Total 35 100 27 100 40 100 19 100
Next land managers were asked to strongly agree (7) or strongly disagree (1) with a statement
about the role that cane-growing plays in the declining health of the Great Barrier Reef (GBR).
Land managers could also select that they did not know or were unsure (8) or neutral (4) about
what role cane growing plays in the declining health of the GBR.
A means analysis indicates that overall in first round data collection, land managers somewhat
agreed that cane growing plays almost no role in the declining health of the Great Barrier Reef.
Whereas, third round data indicates a more neutral stance to the statement.
Table 49: Means analysis of Burdekin sugar cane land manager statement about the role cane growing
plays in the declining health of the Great Barrier Reef
1st Round 3rd Round
n Mean SD n Mean SD
Cane-growing plays almost no role in the declining health of the Great Barrier Reef
38 5.05 1.58 42 4.60 1.82
Note: 1=strongly disagree, 7=strongly agree, *=significant at 5% level
A frequency analysis of the same data shows less agreeance with the statement in third round
data collection than in first round data collection. This may indicate a change in attitude
towards the role that cane growing plays in the declining health of the Great Barrier Reef by
Burdekin cane farmers i.e. that cane growing may play some role in the declining health of the
GBR.
78
Figure 6: Responses from Burdekin sugar cane land managers about the role cane growing plays in the
declining health of the Great Barrier Reef
Participants were asked to write comments about what they thought the two top pressures
were on the GBR. Land manager responses were coded into themes, a full list of anecdotal
comments can be found in Appendix 9. In the first round of data collection Burdekin cane
growers listed climate change/global warming (rising sea temperatures, water temperature) as
the main pressure on the GBR. The second top pressure was also listed as climate change.
In the third round of data collection climate change was listed as the top pressure and urban
development as the second top pressure on the GBR. These results support earlier findings
(Farr et al., 2017d, p. 77) that land managers tend to shift the blame related to water quality
and the health of the Great Barrier Reef to climate change, natural weather events, run-off not
related to farming, fishing, shipping, tourism and urban development rather than consider their
own practices as adding pressure to the GBR.
15.8 18.4
63.2
2.6
26.2 28.6
38.1
7.1
0
10
20
30
40
50
60
70
Somewhat disagree,Disagree, Strongly
disagree
Neutral Somewhat agree,Agree, Strongly agree
Do not know/Not sure
Perc
ent
Cane-growing plays almost no role in the declining health of the Great Barrier Reef
1st Round (n=39) 3rd Round (n=42)
79
Table 50: Burdekin - two top pressures on the health of the Great Barrier Reef
1st Round 3rd Round
Pressure 1 Pressure 2 Pressure 1 Pressure 2
n Percent n Percent n Percent n Percent
Climate Change/Global Warming
8 22.9 8 32.0 13 31.7 2 5.6
Weather/Natural Run-off/Floods/Rainfall
5 14.3 3 12.0 2 4.9 4 11.1
Run-off 5 14.3 2 8.0 3 7.3 4 11.1
Fishing/Shipping/Tourism 4 11.4 0 0.0 4 9.8 4 11.1
Urban Development 3 8.6 4 16.0 3 7.3 9 25.0
Farming (Banana, Cane, grazing and Fruit Growers)
3 8.6 3 12.0 3 7.3 4 11.1
Acidification/CoT/Coral Bleaching
2 5.7 1 4.0 1 2.4 1 2.8
Feral Animals (Pigs) 1 2.9 0 0.0 0 0.0 0 0.0
Other Industry, Mining, Government, Research
1 2.9 3 12.0 5 12.2 1 2.8
No poor water quality 1 2.9 0 0.0 0 0.0 0 0.0
Illegal dumping/Accidental Spills/Pollution
1 2.9 0 0.0 4 9.8 3 8.3
Erosion 0 0.0 0 0.0 0 0.0 1 2.8
Cultivation Practices 0 0.0 1 4.0 0 0.0 0 0.0
Blockages in creeks, cleaning creeks and drains
0 0.0 0 0.0 0 0.0 1 2.8
Construction/Civil Works 0 0.0 0 0.0 0 0.0 0 0.0
Don't know 1 2.9 0 0.0 3 7.3 2 5.6
Total 35 100 25 100 41 100 36 100
6.3.2.7 Sugar Cane Land Managers Results Summary
This section has reported on results from questions related to nutrient and run-off management
practices for growing sugar cane in the Burdekin region, of Queensland Australia.
The results from the analysis show that cane farmers in the Burdekin region have moved from
a goal of maximizing productivity and efficiency and improving farming practices for profit and
environment to increasing viability and financial security and improving productivity and/or
efficiency in farming.
When making decisions to reach their goals, land managers decisions are significantly
influenced by learning and testing new ways of doing things on the farm or property and by
leaving the farm in better condition than it was when the land manager got there. Burdekin
cane farmer’s decisions are also significantly influenced by safeguarding local waterways,
native plants and animals and the Great Barrier Reef. While maintaining health, spending time
with family and friends, maintaining relations with other land managers, and being able to make
their own decisions were also important, they were not seen as influencers to decision making
for cane farmers in the Burdekin. Likewise, financial statements about keeping farming cost
low, maximising profits, minimising risk, keeping a steady cash flow and servicing debt were
also important, but did not influence decisions more in the third year of the study compared to
the first year.
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Nearly all of the land managers were using some form of irrigation practices. The amount of
water used varied and depended on the soil type and season. More than ninety percent of the
land managers reported having zero to 25 percent irrigation run-off from their property. While
the percent of responses was lower (<15%), more land managers reported having between 25
and 50 percent of irrigation run-off from their property in the third year of the study than in the
first.
When considering irrigation management tools, more than half of respondents were using their
own experience to make choices about irrigation tools and their management. In the third year
of the study, seventy percent of land managers were using soil moisture probes. Of which,
forty percent of land managers were using newer technology (g-dots) to identify water use and
predict next irrigation. The vast majority of land managers expected that they would use the
same systems next year.
Land managers have reported differently about whose advice they follow. In the first year of
the study, land managers were following advice about irrigation practices from various advisors
including other cane farmers, private agronomists, researchers, industry extension advisors
and family who are also cane farmers. In the third year, there was a more distinct group of
advisors including private and industry agronomists and family who are also cane growers.
Land managers also listed other industries and government departments as ‘other’ advisors.
It is important to note the influence that networks have on land manager decisions. These
networks may be identified as either positive or negative and may become enablers or barriers
to practice change. The findings support previous recommendations for a land manager
network analysis to ensure that information gatekeepers and opinion leaders influence future
water quality communication strategies (see Hay & Eagle, 2018).
When thinking about scheduling irrigation, Burdekin cane farmer’s decisions are influenced by
the farmers that they respect most and how they are scheduling their irrigation. Land
managers from the Burdekin region indicated that they were not certain that most farmers in
the region would have the technical knowledge to schedule irrigation, although they indicated
that most other land managers would be able to afford the systems. Land managers disagreed
that they were being forced to make the decisions they were making about irrigation scheduling
practices. This is expected, given that most land managers reported that they follow their own
experience for scheduling irrigation, but the sentiment may also be influenced by new and
affordable technologies that are available to indicate when irrigation is required e.g. G-Dots.
The majority of Burdekin cane farmers agreed that the system that they were using to schedule
irrigation was the most effective way of controlling nutrient loss from their property. However,
the results indicate that land managers in the third round of the study compared to the first
year of the study, remain neutral or slightly disagree that the scheduling tools that they are
using are the most effective way of controlling nutrient loss from their property. The results
may indicate a loss of confidence in the current tools used for scheduling irrigation or an
uncertainty in the new tools being used, further investigation is required.
Burdekin cane farmers are tailoring their fertilizer rates to different parts of their property in the
third year of the study more so than in the first year and they are doing it under the influence
of their trusted advisor. However, less land managers identified as using best management
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practice in the third year of the study compared to the first year. When calculating fertilizer
rates, land managers are somewhat influenced by the farmers they respect most and the
people and organisations that think they should be using the system to calculate fertiliser rates.
However, they thought that the system they are using is the most effective way to control
nutrient loss from their property.
When comparing the same land managers in first and third year data collection, the data
indicates that there has been a change in the way land managers calculate fertiliser application
rates. Slightly more land managers in the third year of the study are using their advisor to
calculate fertiliser application rates than in the first year of the study. Less land managers
reported using more fertiliser on high yielding blocks, while more are estimating fertiliser rates
from farm yield. Nearly two thirds of land managers reported tailoring their fertiliser rates.
However, of concern is that less land managers are using industry standard rates for district
yield potential in third round (15.4%) compared to first round (25.5%) data collection? While
the data indicates changes in the way that land managers are calculating their fertiliser
application rates, the results cannot determine if land managers are using best practice
management techniques to calculate fertiliser rates or some other method. In addition, the
sample is very small and therefore not representative of the entire Burdekin region.
When handling run-off, just over one third of land managers are following conventional run-off
management practices or using other practices (buffer zones, grass and drains, contouring
and silt traps), which meet minimum expectations or are current practices as promoted by the
industry. The data indicates that land managers decisions about handling run-off were
somewhat influenced by ‘farmers who they respect most’ in the first round, but more neutrally
influenced by respected farmers in the third round and that they follow the advice of people or
organisations whose advice they think they should follow. Given that land managers indicated
that their primary advisor is either a private agronomist or an industry extension officer, this
may indicate a stronger compliance with best management practice. Compliance will depend
on if the private agronomist and/or the industry extension officer is following best practice
management or not. Significantly, land managers reported that the method they used to
handle run-off was the most efficient way to control nutrient loss from their property.
When comparing the same land managers who completed the survey in the first round and
again in the third round, the data showed that there has been minor changes in the way that
land managers are handling run-off. More land managers are using recycle pits and capturing
run-off. However, less land managers reported using recycle pits with adequate pumping
capacity to recycle water. Around the same amount of land managers reported doing
something other than what was listed to handle run-off, including sediment traps, grass and
drains, buffer zones, contouring or lazer levelling with silt traps or they are using natural
drainage filters. While the results indicate changes in the way that land managers are handling
run-off, the results cannot determine if land managers are using best practice management
techniques to handle run-off or some other method.
Around half of the land manager respondents identified that they were using other innovative
practices to manage nitrogen and/or run-off. When matching responses to the ABCD
Framework, it was identified that most of the practices that land managers noted when
selecting an ‘other’ practice, met best management to aspirational practice expectations in the
third round of data collection.
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Overall the land managers surveyed neither agreed nor disagreed that nutrient losses from
their property have an impact on local streams, rivers and waterways. On closer inspection,
in the third round, the data shows that less land managers agreed that nutrient loss from their
property has no impact on water quality, indicating an acknowledgment that nutrient loss from
their property did have some impact on water quality in local streams, rivers and waterways.
When asked what the top two causes of poor water quality in local streams, rivers and water
ways were, first round land managers cited farming (banana, cane, grazing and fruity growing)
and weeds. In the third round land managers cited farming to be both the top and second top
cause of poor water quality in local streams, rivers and waterways.
Overall land managers in first round somewhat agreed that cane growing plays almost no role
in the declining health of the Great Barrier Reef. Whereas, third round data indicates a more
neutral stance to the statement.
Participants identified climate change and global warming as the top two pressures on the
health of the GBR in first round and in third round of the study, followed by urban development
in both rounds.
6.3.3.1 Factors that influence land manager decisions
In order to understand the factors that influence their decisions, land managers were asked to
identify the two most important things that they hoped to achieve for their farm or property.
Land managers responses were coded into first round and third round data, which resulted in
the same goals over the duration of the study. Grazing land manager’s main goals are to have
a sustainable and viable grazing business, to pass the property on to future generations in a
better condition than when they found it by improving pastures, groundcover and reducing
weeds, highlighting a motivation to participate in good farming practices.
Table 51: Burdekin grazing land managers personal goals to achieve on farm/property
Goal 1 Goal 2
Sustainable and viable grazing business Improving the land, leave the country better than when we found it
Pass on a healthy property to future generations Pass on a productive property to next generation
Improving pastures, groundcover, reducing weeds
Sustainable grazing business
6.3.3.2 Decision making drivers
The next question asked land managers how important they thought a set of 21 statements
were when making decisions about what to do on their farm or property (See Table 52). The
participants were asked to choose the importance of each statement on a scale of 1-extremely
unimportant to 8 where 7 was equal to extremely important (essential) and 8 was equal to ‘I
don’t know’, the number 4 was listed as neutral. A means test was applied to compare first
and third round land manager responses. Followed by an independent samples t-test to
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establish any significant difference in the responses. The following section reports on the
results from Table 52.
Family, friends and other land manager influences
The first set of statements considers family, friends, health and other land manager influences
when making decisions. All of the statements were more important in the third round of data
collection than they were in the first round, except for ‘maintaining traditions and heritage’,
which remained the same. While ‘maintaining physical and mental health of family’ was
selected as important to extremely important, by contrast, land managers selected ‘maintaining
traditions and heritage’ as being less important, rating the statement between neutral and
somewhat important when making decisions on their farm or property. An independent t-test
showed that none of the statements were statistically different between data collection points,
see Table 52.
Financial influencers
Statements that considered financial influences i.e. minimising risk, maximising profits and
keeping a steady cash flow were indicated as important to very important. However, similar to
sugar cane responses, grazing land managers rated them as less important to consider when
making decisions about what to do on the farm in the third round of data collection compared
to the first round data collection. Keeping farming cost low and servicing debt moved from
somewhat important to important in the third round of data collection compared to the first
round. There was no statistical difference for decision influencers between data collection
points, see Table 52.
Land management influencers
The next set of statements consider land management influences when making decisions.
There is a statistical difference between first and third round data collection in one land
management statement. Land managers felt that ‘having time to pursue hobbies’ was more
important in third round data (M=5.01; SD=1.72) than in the first round (M=4.26, SD=1.91;
t(139)=2.47, p=.01, two tailed) when making decisions about what to do on their property.
While the other statements were identified as more important in third round compared to first
round, there was no statistical difference between statements over the data collection points.
Similar to Burdekin sugar cane land managers, ‘being able to make their own decisions about
their farm/property’ was the most important for graziers in the first and third round of data
collection. ‘Having efforts recognised by the wider community’ was the least important
consideration in both first and third round data collection for grazing land managers when
making decisions about what to do on their properties. There was no statistical difference for
decision influencers between data collection points, see Table 52.
Farming practices
When considering how farming practices influence decisions, all of the statements were less
important in the third round of data collection compared to the first round. While rated as
important to very important, the scores show that leaving the farm in better condition is slightly
less important in third round data collection than it was in first round data collection. While
maintaining or improving water supplies and storage and minimising sediment run-off or
nutrient losses were rated as important to very important, there is no statistical difference
between land manager responses in the first round to the third round, indicating that these
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factors are always considered important to decisions about what to do on the land managers
farm or property, see Table 52.
Safeguarding local waterways, native plants and animals and the Great Barrier Reef
The final set of statements indicate that safeguarding local waterways, the Great Barrier Reef
(GBR) and native plants and animals are more important to land managers in the third round
of data collection compared to the first round. There is a statistical difference between first
round and third round data for two of the three statements. Helping to safeguard native plants
and animals (first round M=5.63; SD=1.56 and third round (M=5.82, SD=1.20; t(139)=2.13,
p=.03, two tailed) and Helping to safeguard the Great Barrier Reef (first round M=5.44;
SD=1.79 and third round (M=5.99, SD=1.26; t(139)=2.15, p=.03, two tailed) both increased in
importance between data collection points. While the level of importance of land manager
decision influencers about what to do on the farm or property has increased between first and
third year data collection, the statements about safeguarding native plants and animals and
helping to safeguard the GBR are more significant than safeguarding local water ways, see
Table 52.
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Table 52: Burdekin sugar cane land manager responses decision making drivers
1st Round 3rd Round
n Mean SD n Mean SD
Maintaining physical and mental health of family 62 6.50 0.99 79 6.58 1.15
Spending face-to-face time with family and friends 62 5.95 1.12 79 6.24 1.06
Maintaining good relations with other farmers/graziers in the local area 62 5.71 0.88 79 5.92 1.05
Keeping in contact with family and friends in other ways (e.g. via phone, through social media) 62 5.61 1.41 79 5.96 1.24
Maintaining family traditions and heritage 62 4.66 1.70 79 4.66 1.93
Minimising risk (of very high costs or very low income) 62 6.32 0.95 79 6.28 1.07
Maximising farm profits (income minus costs) 62 6.29 1.14 79 6.19 1.21
Keeping a stable (steady) cash-flow 62 6.18 1.12 79 6.08 1.39
Keeping farm costs low 62 5.92 1.06 79 6.13 1.16
Servicing debt 62 5.95 1.53 79 6.14 1.44
Being able to make your own decisions about your farm/property 62 6.44 0.99 79 6.56 1.00
Learning about and testing new ways of doing things on your farm/property 62 5.89 1.28 79 6.11 1.13
Sharing new ideas with others 62 5.35 1.28 79 5.61 1.31
Having time to pursue hobbies* 62 4.26 1.91 79 5.01 1.72
Having efforts recognised by the wider community 62 3.73 1.87 79 4.32 1.84
Leaving the land/farm in better condition than it was when you first started managing it 62 6.66 0.70 79 6.65 0.93
Maintaining/improving water supplies and storages 62 6.58 0.69 79 6.57 1.00
Minimising sediment run-off and/or nutrient losses 62 6.34 1.04 79 6.52 0.96
Helping to safeguard local waterways 62 5.92 1.26 79 6.33 1.02
Helping to safeguard native plants and animals* 62 5.63 1.56 79 5.82 1.20
Helping to safeguard the Great Barrier Reef* 62 5.44 1.79 79 5.99 1.26
Note: 1=strongly disagree, 7=strongly agree, *=significant at 5% level
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6.3.3.3 Pasture spelling practices
Land managers were asked to answer a series of questions about their pasture spelling
practices. The responses from the first round of data were compared to responses from the
third round of data to identify any changes in pasture spelling practices.
When asked if respondents spelled their paddocks during the most recent wet season, the
majority in both first and third round data collection selected that they did spell their paddocks
in the most recent wet season.
The majority of land managers selected that they were spelling about ¼ of their paddocks
during the wet season, however less (23.9%) were practicing the method in the third year
compared to in the first year (38.5%), see Table 53. Approximately 69% of respondents chose
the response that they spelled their paddocks for three months or more and 23% chose two
months or more. The remainder spelled their paddocks for four weeks or less.
Table 53: Proportion of paddocks that were spelled by Burdekin Grazing Land Managers in the most
recent Wet Season
1st Round 3rd Round
n Percent n Percent
All 8 20.5 6 13.0
About ¾ 5 12.8 7 15.2
About ½ 6 15.4 16 34.8
About ¼ 15 38.5 11 23.9
Less than ¼ 5 12.8 6 13.0
Total 39 100 46 100
Respondents were asked to add comments about their spelling practices and about if they
planned to use the same spelling practice next year. Nearly 90% of the respondents indicated
that they would do the same in the next year. Two percent said they would not do the same
practice next year and nearly 6% said that they would do something different, as indicated in
Table 54.
Table 54: Anecdotal comments about what Burdekin grazing land managers plan to do differently when
spelling paddocks next year
1st Round 3rd Round
Hoping to sell enough cattle to be able to set up one more trough and do internal fencing to be able to spell paddocks
Prep before more cattle
More intensive grazing and more regular spelling (or for longer periods)
Still going to spell, but going to hit them a bit harder.
Next time, looking to burn them [the paddocks] if the opportunity presents itself
The same but for a longer period
Table 55 lists the responses from the Burdekin grazing land managers about how they spelled
their paddocks in the most recent wet season.
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Table 55: Anecdotal Responses from Burdekin Graziers about how they spell their paddocks
1st Round 3rd Round
• 60% Reduced 01/13. 95% Reduced 01/15.Destocked 03/16
• Available funds are being used on weed spraying expenses and don't have the money to put up internal fencing
• Cattle are on rotation moved every four days during growing season
• Every paddock is spelled for 100 days 3 times per year - That's 300 days approx. per year
• Every year is unique - flexibility is key
• I spell 25% of the property every year. This used to be for a full wet season. I am now going into a rotational grazing strategy, so this will involve more country being spelled more often but also grazed more intensively for shorter periods.
• Some, depends on season. Some rotational, spelling etc.
• Various, cattle in one mob, move in high density groups spelling some paddocks for up to 12 months
• We are trying to implement this, but no rain for 4 years, and lack of funds to fence more paddocks off is not helping
• Yes, I have been spelling paddocks during the wet for the last 25 yrs.
• We use rotational grazing systems on this property. We have employed this practice for 20 years and during this time, we have been able to manage Parthenium and other invasive weeds quite well and move from a very degraded pasture state when we took over management, to a very good to excellent pasture at present. A result of our management practices saw the CSIRO conduct a ground-truthing case study on our property a couple of years back as they could see an improvement in our groundcover over the past 20 years. We like to spell a paddock (sometimes up to 6 months or more, depending on the season). Once the grasses have seeded, it is quite safe to graze. How long each paddock is grazed depends entirely on the season. We do not run our property to full capacity as we like to have at least 2 paddocks per herd of cattle as this allows us to rotationally graze. Rainfall has a lot to do with our rotational grazing pattern and drought really has an impact.
• ~70% of our property is spelled at any one time, for an average of ~5 months.
• Depending on soil type, fencing paddocks according to soil type,
• Been in drought for years; did some spelling on some paddocks;
• Can't remember the last wet season we had. Have juggled our cattle the best way we can to get through lack of rain.
• 80% of my property has no cattle at one time
• Depends on amount of rain and out compete the weeds-depend on seasonal conditions-90 days/year
• Essential management practice
• Does Cell Grazing - Every paddock gets spelled most of the year.
• Haven't had a wet season for nearly 5 years
• Latest season there was nothing to spell. Typically we would. If there was rain.
• No need to spell if they are not overstocked only spell after a fire or ploughed
• Not in the past couple of years but it is a practice that I to do
• Our stock is on a rotation. We do spell certain paddocks for the time when Chinese apple have fruit.
• Rotational graze to utilise new growth in peak growing season
• Rotational grazing over wet season spelling
• Spelling during growing season is vital. We try to rotate different paddocks to spell each year
• We graze only 1 paddock at a time, other 6 paddocks are rested
• We shut up our dam squares, stops cattle from going to their habitual grazing
• When you are spelling paddocks a graze in the wet season is just as important been rotating for 25 years
• Yes. Each paddock is spelled according to its Stock Days per Hectare per 100mm of rainfall and ground truthed by pasture monitoring during each rotation. Currently we aim to rest each paddock for approx. 240 days per year.
• Yes. Rotate the paddocks. Always spelled.
Advice land managers follow when making decisions about paddock spelling
Land managers were asked to rank from 1= most important to 13=least important whose
advice they follow most when spelling paddocks. A cross tabulation between ‘advice land
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managers follow when spelling paddocks’ and ‘round of data collection’ compared responses
from the first and third rounds of data collection, see Table 56 and Table 57.
In the first round of data collection the respondents identified ‘Other graziers’ as their most
important advisor, followed by ‘Other. Who?’ for which respondents listed trusted advisors as
‘them self or their partner’, ‘consultants’, ‘trials and education programs’ and holistic graziers
and educators, other successful graziers and grazing best practice and local council/
authorities that at not natural resource management groups. ‘Family who are also graziers’
was ranked as the third most important advisor. The next most important advisors were NQ
Dry Tropics and other extension officers, see Table 56 for a list of extension other extension
officers.
Table 56: Advice Burdekin grazing land managers follow when making decisions about paddock spelling,
ranked 1 most important to 13 least important – 1st Round Data Collection
Advisor 1st Round
Rank 1 2 3 4 5 6 7 8 9 10 11 12 13 Total
Other graziers 10 9 5 2 2 0 0 0 0 0 0 0 0 28
Other. Who? * 14 4 3 1 1 0 0 0 0 0 0 1 1 25
Family who are also graziers 20 1 0 0 0 1 0 0 0 0 0 0 0 22
People from NQ Dry Tropics 6 6 3 3 0 0 0 0 0 0 0 0 0 18
Extension officers. From where? ** 3 3 4 3 1 0 0 0 0 0 0 0 0 14
Researchers 1 1 6 2 1 1 0 0 0 0 0 0 0 12
Landcare 1 3 1 3 0 0 0 0 0 0 0 0 0 8
Meat & Livestock Australia 2 1 2 1 0 0 1 0 0 0 0 0 0 7
People from government departments. Which departments? ***
1 2 1 1 0 0 0 0 1 0 0 1 0 7
Agforce 2 0 0 2 0 0 0 0 1 0 0 0 0 5
Private Agronomists 1 1 0 1 1 0 0 0 0 0 1 0 0 5
Non-farming family/friends 1 0 1 0 0 0 0 1 0 0 0 0 0 3
QLD Farmers Federation 1 0 0 1 0 0 0 0 0 1 0 0 0 3
*Other. Who? (number of responses): their own experience (11); consultants e.g. Resource Consulting Services (8); trials/education programmes (2); holistic management graziers/educators (1); other successful graziers (1); grazing best practice (1); local council/authority, not NRM (1) **Other Extension, from where?: DAF (6); NQDT (2); Department of Natural Resources (2); CSIRO (1); Northern Gulf Resource Group (1) ***Government Departments: DAF/DPI (2)
In the third round of data collection the most trusted advisor was also identified as ‘family who
are graziers’ and ‘other graziers’ as well as “Other. Who?” which were listed as their ‘own
experience’, ‘consultants’, ‘trials and education’ and ‘holistic management graziers/ educators’
and ‘other successful graziers’ and ‘industry representatives and government departments’.
People from NQ Dry Tropics ranked as the fourth advisor most followed when making
decisions about spelling paddocks (see Table 57).
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Table 57: Advice Burdekin grazing land managers follow when making decisions about paddock spelling, ranked 1 most important to 13 least important – 3rd Round Data Collection
Advisor 3rd Round
Rank 1 2 3 4 5 6 7 8 9 10 11 12 13 Total
Family who are also graziers
21 9 4 1 1 0 0 1 0 0 1 0 0 38
Other graziers 14 12 6 3 2 0 0 0 0 1 0 0 0 38
Other. Who? 28 5 0 1 0 1 0 0 0 0 0 2 2 39
People from NQ Dry Tropics
8 8 5 3 5 1 2 1 0 0 0 0 0 33
People from government departments. Which departments?
1 3 5 2 0 0 1 1 0 1 0 4 1 19
Extension officers. From where?
3 3 3 2 3 1 0 0 0 1 1 1 0 18
Researchers 2 2 3 3 1 0 2 1 1 0 1 0 0 16
Meat & Livestock Australia
1 1 3 1 0 2 2 2 3 0 0 0 0 15
Landcare 0 1 1 3 1 3 0 1 1 0 2 0 0 13
Agforce 0 1 0 2 1 1 0 2 0 3 1 0 0 11
Private Agronomists
1 3 1 0 0 1 1 0 0 0 0 3 0 10
Non-farming family/friends
0 2 0 0 0 0 0 0 0 0 3 3 0 8
QLD Farmers Federation
0 0 0 0 1 1 0 0 1 1 2 1 1 8
*Other. Who? (number of responses): their own experience (17); consultants e.g. Resource Consulting Services (9); trials/education programmes (2); holistic management graziers/educators (1); other successful graziers (1); dependent on rainfall (1); industry representatives (1) **Other Extension, from where?: DAF (7); NQDT (1). ***Government Departments: All of them (1), DPI (1)
Non-farming family and friends, the Queensland Farmers’ Federation (QFF) and private
agronomists were ranked as least important advisors to follow when making decisions about
spelling paddocks during the wet season. Land managers who selected ‘People from
government departments. Which departments? also commented negatively about the
departments level of knowledge at a policy level reinforcing the lack of trust of government
agencies (see Eagle et al., 2016b).
“Not at all!! They have NO IDEA!! NPRSR & the forestry dept. are dangerously
idealistic & ignorant of actual outcomes for the land” ranked least likely to
follow advice by land managers.
“State and Federal Governments. The ministerial misuse of information
gathered from our properties has made these departments untrustworthy. The
staff are not at fault - their political policy directors are destroying a once very
trusted source of information” ranked least likely to follow advice by land
managers.
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Attitudes and motivations associated with pasture spelling practices
The next question asked participants how important a set of listed statements were to land
managers when making decisions about pasture spelling practices. The participants were
asked to choose the importance of each statement on a scale of 1-strongly disagree to 7
strongly agree, with 4 being neutral.
The first set of statements considered influencers when making decisions about pasture
spelling practices. Burdekin graziers follow their chosen pasture spelling practice because
the people or organisations whose advice they follow most think that they should use the
spelling practice (first round M=5.56, SD=1.99; third round M=5.28, SD=1.86). The data
indicates that land managers decisions about pasture spelling practices are also somewhat
influenced by ‘graziers that they respect’ in both first (M=5.26, SD=1.78) and third round
(M=5.72, SD=1.46) data. The data (first round M=4.26, SD=2.35; third round M=4.16,
SD=2.28) indicates that graziers held a neutral stance on whether other graziers could afford
the systems being used for pasture spelling. Similarly, they offered a neutral stance about
their thoughts on other graziers having the technical knowledge to implement the current
pasture spelling practices (first round M=4.06, SD=1.99; third round M=4.22, SD=1.97). Land
managers did not agree that they were being forced to use the methods, see Table 58. An
independent t-test produced no significant difference in scores for each statement.
Table 58: Burdekin grazier land manager attitudes and motivations associated with pasture spelling
practices
1st Round 3rd Round
N Mean SD N Mean SD
The people/organisations whose advice I follow most think I should do this
54 5.56 1.99 74 5.28 1.86
The graziers I respect most do this 54 5.26 1.78 74 5.72 1.46
Most graziers in this region would not be able to afford to do this
54 4.26 2.35 74 4.16 2.28
Most graziers in this region would not have the technical knowledge to do this
54 4.06 1.99 74 4.22 1.97
I only use this system for spelling paddocks during the wet season because I am forced to. Who/what is forcing you?
54 2.98 2.51 74 2.26 2.01
Note: 1=strongly disagree, 7=strongly agree, *=significant at 5% level
The second set of statements ask the land manager to read the statement and respond how
using their method for pasture spelling practices measures when compared to other ways of
managing pasture spelling practices.
While all statements have high agreement (see Table 59) ‘the best way to meet my own
personal goals’ and ‘the most effective way of controlling erosion on my property’ are the most
agreed with motivators for using the method to spell paddocks that the land manager is using.
Grazing land managers agreed that ‘reducing business risk’ and ‘maintaining good cash-flow’
were also considered when thinking about the system for spelling paddocks or not during the
wet season. While being time consuming or labour intensive were neutral to motivation. An
independent t-test produced no significant difference in scores for each statement.
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Table 59: Compared to other ways of managing pasture spelling, what motivates Burdekin grazier land managers to use the system that they use?
1st Round 3rd Round
N Mean SD N Mean SD
The best way to meet my own personal goals 54 6.09 1.39 74 6.04 1.12
The most effective way of controlling erosion on my property
54 5.80 1.59 74 5.66 1.62
The best way to reduce business risk 54 5.78 1.36 74 5.82 1.22
The best way to maintain good cash-flow 54 5.59 1.52 74 5.70 1.37
The least time-consuming (or labour intensive) 54 4.43 1.97 74 4.91 1.87
Note: 1=strongly disagree, 7=strongly agree, *=significant at 5% level
Has pasture spelling practices changed?
To establish whether there was a change in the way land managers manage pasture spelling
between first and third round data collection, a multiple response cross-tabulation was
performed using the land manager unique identification number to identify graziers in each
round of data collection (1=Grazier First Round and 3=Same Grazier Third Round). However,
the number of graziers who completed the survey in both rounds was too small to draw
conclusions from the analysis.
Adjusting stock rates to paddock conditions practices (other than wet-season spelling)
Land managers were asked to answer a series of questions about adjusting stock numbers to
paddock conditions. The responses from the first round of data were compared to responses
from the third round of data to identify any changes in adjusting stock numbers.
Graziers in the Burdekin are adjusting stock numbers in both first round (96.3%) and third
round (90.4%) data collection. Around 90% of graziers in first round and 89% of graziers in
third round have an end-of-season target for pasture condition.
The majority of graziers aim to leave between one third and one half of the feed that was grown
that season in the paddock at the end of the season. Graziers mostly achieve these targets
between five and seven years in every ten years. The vast majority of graziers in first round
(94.4%) and third round (90.4%) plan to adjust stock numbers to manage pasture the same
way next year (Table 60).
Table 60 also lists management practices for those graziers that intend to do something
different in the coming year.
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Table 60: Burdekin grazier intentions for adjusting stock rates to paddock conditions (other than wet season spelling)
ABCD
Framework 1st Round 3rd Round
How much feed to you aim to leave in the paddock at the end of the season?
n Percent n Percent
Less than 1/3 of the feed that was grown that season
C 3 6.1 12 18.5
Between 1/3 and 1/2 of the feed that was grown that season
C/B 37 75.5 44 67.7
Between 1/2 and 3/4 of the feed that was grown that season
B 8 16.3 8 12.3
More than 3/4 of the feed that was grown that season
B/A 1 2.0 1 1.5
1st Round 3rd Round
Roughly how often do you achieve this? n Percent n Percent
Less than 3 in 10 years C 8 16.3 10 15.4
Between 5 and 7 years in 10 C/B 16 32.7 19 29.2
Between 3 and 5 years in 10 B 7 14.3 15 23.1
More than 7 years in 10 B/A 18 36.7 21 32.3
1st Round 3rd Round
Do you plan to do this next year? n Percent n Percent
Yes 51 94.4 66 90.4
No, I plan to do something different 3 5.6 3 4.1
If you plan to do something different, what is it?
1st Round 3rd Round
• Adjust stocking rate to grass stocks, but more intensively.
• Put up internal fences to rotate and spell pastures if we have the money to do so
• We just need rain to actually put some targets in place and carry out more spelling
• Full crop pasture management
• Wait for rain
• For some paddocks it will be the same, sometimes we have half the amount of cattle because you sell a few extra at times. Stocking rate and spelling.
Advice land managers follow when making decisions about adjusting stocking rates?
Land managers were asked to rank from 1= most important to 13=least important whose
advice they follow most when making decisions about adjusting stocking rates. A cross
tabulation between ‘advice land managers follow when adjusting stocking rates’ and ‘round of
data collection’ compared responses from the first and third rounds of data collection (see
Table 61 and Table 62).
In the first round of data collection, ‘other graziers’ was ranked as the most followed advisor
overall, by contrast ‘family who are also graziers’ was the highest ranked as most important
advisor. This was followed by ‘Other. Who?’ which included land managers own experience,
consultants, other successful graziers, grazing best practice and local council or authority that
is not a NRM, then ‘people from NQ Dry Tropics’, see Table 61.
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Table 61: Advice Burdekin grazing land managers follow when making decisions about stocking rates, ranked 1 most important to 13 least important – 1st Round Data Collection
Advisor 1st Round
Rank 1 2 3 4 5 6 7 8 9 10 11 12 13 Total
Other graziers 9 8 5 3 1 0 0 0 0 0 0 0 0 26
Family who are also graziers 20 1 2 1 0 0 0 0 0 0 0 0 24
Other. Who? 15 2 5 0 0 0 0 0 0 0 0 1 0 23
People from NQ Dry Tropics 6 3 4 3 0 0 0 0 0 0 0 0 0 16
Extension officers. From where? 2 2 4 2 0 0 0 0 0 0 0 0 0 10
Researchers 2 3 3 1 0 0 1 0 0 0 0 0 0 10
People from government departments. Which departments?
3 3 2 0 0 0 0 0 0 0 0 0 1 9
Meat & Livestock Australia 1 1 2 2 0 1 0 0 0 0 0 0 0 7
Landcare 0 3 2 2 0 0 0 0 0 0 0 0 0 7
Private Agronomists 1 0 2 0 0 0 0 1 0 0 0 0 0 4
Non-farming family/friends 0 1 1 0 0 0 0 0 0 0 1 0 0 3
Agforce 0 0 1 0 0 0 0 0 1 0 0 0 0 2
QLD Farmers Federation 0 0 1 0 0 0 0 0 0 1 0 0 0 2
*Other. Who? (number of responses): their own experience (11); consultants e.g. Resource Consulting Services (4); trials/education programmes (1); other successful graziers (1); grazing best practice (1); local council/authority, not NRM (2) **Other Extension, from where?: DAF (5); Department of Natural Resources (2); CSIRO (1); NQDT (1) ***Government Departments: DAF/DPI (5)
In the third round, ‘Other. Who?’ was ranked as the most important advisor and included the
land managers own experience, consultants, trials and education programmes, industry
representatives and that advice was dependent on rainfall. ‘Family who are also graziers was
next most important, followed by ‘other graziers’ as the advisors graziers follow when making
decisions about stocking rates, see Table 62.
Table 62: Advice Burdekin grazing land managers follow when making decisions about stocking rates,
ranked 1 most important to 13 least important – 3rd Round Data Collection
Advisor 3rd Round
Rank 1 2 3 4 5 6 7 8 9 10 11 12 13 Total
Other. Who? 30 5 0 2 0 1 0 0 0 0 1 0 1 40
Family who are also graziers 19 9 3 0 3 0 0 1 1 0 0 0 0 36
Other graziers 12 13 4 3 1 1 0 1 0 0 0 0 0 35
People from NQ Dry Tropics 6 8 7 3 3 1 0 2 0 1 0 0 0 31
Extension officers. From where? 4 1 2 4 2 1 0 0 1 0 2 1 0 18
People from government departments. Which departments?
0 5 4 0 0 0 0 0 1 1 1 4 1 17
Meat & Livestock Australia 1 1 4 0 0 2 2 3 1 0 1 0 0 15
Researchers 3 3 3 1 1 1 2 0 0 0 0 1 0 15
Private Agronomists 1 2 1 2 0 1 1 1 0 1 0 2 0 12
Landcare 0 1 3 2 1 1 1 0 1 0 1 1 0 12
Agforce 0 1 1 2 0 1 2 0 1 2 0 1 0 11
Non-farming family/friends 0 0 1 0 0 0 0 0 2 2 0 2 0 7
QLD Farmers Federation 0 0 0 1 1 0 0 1 0 1 0 1 2 7
*Other. Who? (number of responses): their own experience (16); consultants e.g. Resource Consulting Services (7); trials/education programmes (2); industry representatives (2); dependent on rainfall (1) **Other Extension, from where?: DAF (9); Northern Gulf Resources (2). ***Government Departments: DAF (8)
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Attitudes and motivations associated with adjusting stock rates to paddock conditions
(other than wet season spelling)
The next question asked participants how important a set of listed statements were to land
managers when making decisions about adjusting stocking rates. The participants were asked
to choose the importance of each statement on a scale of 1-strongly disagree to 7 strongly
agree, with 4 being neutral.
The first set of statements considered influencers when making decisions about adjusting
stocking rates. Burdekin graziers follow their chosen method for adjusting stocking rates
because the graziers they respect most are using the same practice. There is a higher
agreeance in third round data (M=6.07, SD=1.18) compared to first round data (M=5.63,
SD=1.53). The data indicates that land managers decisions about adjusting stocking rates are
also somewhat influenced by ‘the people/organisations whose advice I follow most think I
should do this’ in both first (M=5.54, SD=1.94) and third round (M=5.36, SD=1.76) data. First
and third round data indicates that graziers held a neutral stance on the statement ‘other
graziers having the technical knowledge to implement the current pasture spelling practices’
(first round M=4.44, SD=2.02; third round M=4.22, SD=2.16), indicating that they were not sure
of other land managers technical knowledge. Land managers disagreed that graziers could
not afford the systems being used for adjust stocking rates (first round M=3.54, SD=2.25; third
round M=3.82, SD=2.28) and they also did not agree that they were being forced to use the
methods, see Table 63. An independent t-test produced a significant difference in the scores
between rounds of data collection for the statement ‘I only do this because I am forced to. What
or who is forcing you?’ The means score indicated a stronger dis-agreeance in the third round
than in the first round of data collection.
Table 63: Burdekin grazier land manager attitudes and motivations associated with adjusting stocking
rates
1st Round 3rd Round
n Mean SD n Mean SD
The graziers I respect most do this 54 5.63 1.53 73 6.07 1.18
The people/organisations whose advice I follow most think I should do this
54 5.54 1.94 73 5.36 1.76
Most graziers in this region would not have the technical knowledge to do this
54 4.44 2.02 73 4.22 2.16
Most graziers in this region would not be able to afford to do this
54 3.54 2.25 73 3.82 2.28
I only do this because I am forced to. Who/what is forcing you?*
54 3.13 2.66 73 2.16 1.97
Note: 1=strongly disagree, 7=strongly agree, *=significant at 5% level
The mean scores for ‘I only do this because I am forced to’ show disagreement with the
statement, see Table 63. The anecdotal responses indicate that while no-one is forcing
grazing land managers to adjust their stocking rates, in the first round of data collection they
felt that they were forced to adjust their stocking rates by the drought, nutrition management,
pasture condition, and by their management plans. In the third round of data they indicated
that the force was coming from succession goals, knowledge that adjusting stocking rates is
essential and from pressure from the government, see Table 64.
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Table 64: Anecdotal comments from Burdekin land managers about who/what is forcing them to adjust stocking rates
1st Round 3rd Round
• Drought is a key influence
• For our cows to calve each year they need to have a rising plan of nutrition through pregnancy and lactation. We achieve this through wet and dry lick supplement depending on animal age. These are only effective if you have a reasonable body of roughage to offset the supplement program
• Keep pasture in good condition and keep cattle performing
• Sustainability, pasture health
• Yes management plan forces me to - I made the plan and I need to stick with it. And environment.
• Just the way we do it
• Kids - next generation
• Knowledge that it is essential
• Too dry
• Weather dependent and feel pressure from Govt.
The second set of statements ask the land manager to read the statement and respond how
using their method for adjusting stocking rates measures when compared to other ways of
managing stocking rates.
While all statements have high agreement (see Table 65) ‘the best way to meet my own
personal goals’ and ‘the best way to reduce business risk’ are the most agreed with motivators
for using the method to adjust stocking rates that the land manager is using. Grazing land
managers agreed that ‘controlling erosion’ and ‘maintaining good cash-flow’ were also
considered when thinking about the system for adjusting stocking rates or not during the wet
season. While being time consuming or labour intensive were neutral to motivation to adjust
stocking rates. An independent t-test produced no significant difference in scores for each
statement.
Table 65: Compared to other ways of adjusting stocking rates, what motivates Burdekin grazier land
managers to use the system that they use?
1st Round 3rd Round
n Mean SD n Mean SD
The best way to meet my own personal goals 54 6.31 1.08 73 6.01 1.11
The best way to reduce business risk 54 6.00 1.18 73 6.01 1.07
The most effective way of controlling erosion on my property
54 5.89 1.41 73 5.71 1.37
The best way to maintain good cash-flow 54 5.83 1.26 73 5.82 1.12
The least time-consuming (or labour intensive) 54 4.70 1.74 73 4.78 1.92
Note: 1=strongly disagree, 7=strongly agree, *=significant at 5% level
Has adjusting stock rates to paddock conditions practices (other than wet-season
spelling) changed?
To establish whether there was a change in the way land managers adjust stocking rates
between first and third round data collection, a multiple response cross-tabulation was
performed using the land manager unique identification number to identify graziers in each
round of data collection (1=Grazier First Round and 3=Same Grazier Third Round). However,
96
the number of graziers who completed the survey in both rounds was too small to draw
conclusions from the analysis.
6.3.3.4 Stock management around waterways
Land managers were asked to answer a series of questions about stock management around
waterways. The responses from the first round of data were compared to responses from the
third round of data to identify any changes in stock management around waterways.
When asked if respondents managed stock around their waterways during the most recent wet
season, the majority in both first and third round data collection selected that they did spell
their paddocks in the most recent wet season.
When asked what practices land managers were using to manage stock around waterways,
31.5% of first round respondents selected that they prevent cattle from accessing some
waterways at all times, by contrast in the third round, only 8.8% of respondents were using the
practice (this change may be due to the extended drought in the area, or Table 66, may offer
some alternative management practices). More land managers in third round (30.9%) were
preventing access to some waterways during the wet season, when compared with first round
(24.1%). Around the same amount of land managers in first round (18.5%) and third round
(19.1%) were not preventing cattle from accessing water points. Nearly 12% in third round
data collection were preventing cattle from accessing waterways in the wet season and less
than 5% in both rounds of data collection prevented cattle from accessing waterways at all
times. Grazing land managers have been using these practices to manage their land for
between 1 and 30+ years. Most of the grazing land managers are planning to do the same
practice in the next year. Those that are doing something different have listed fencing off areas
or adding extra water troughs as their management plan, see Table 66.
97
Table 66: Burdekin land manager’s practices for managing stock around waterways
1st Round 3rd Round
n Percent n Percent
How do you manage stock around waterways?
I prevent cattle from accessing some waterways at all times 17 31.5 6 8.8
I prevent cattle from accessing some waterways during the wet season
13 24.1 21 30.9
I do not prevent cattle from accessing waterways 10 18.5 13 19.1
*Other. Please tell us what you do 9 16.7 17 25.0
I prevent cattle from accessing all waterways during the wet season
3 5.6 8 11.8
I prevent cattle from accessing all waterways at all times 2 3.7 3 4.4
54 100 68 100
How long have you used this system to manage stock around waterways?
n Percent n Percent
1-5 Years 10 19.2 12 18.2
6-10 Years 13 25.0 20 30.3
11-20 Years 20 38.5 22 33.3
21-25 years 2 3.8 1 1.5
26-30 Years 3 5.8 3 4.5
31 Years + 4 7.7 8 12.1
52 100 66 100
Do you plan to do this next year? n Percent n Percent
Yes 51 94.4 66 97.1
If you plan to do something different, what is it?
1st Round 3rd Round
Fence off more waterways More fencing
put in extra trough and do internal fencing and this will give us five paddocks
Hoping to get grant for fencing, otherwise it will remain the same
Those that were doing something else were preventing cattle from accessing waterways some
of the time, using bore water to manage cattle away from creeks and using a combination of
practices to manage stock around their waterways, see Table 67.
98
Table 67: Anecdotal comments from Burdekin grazing land managers about other practices they are using to manage stock around waterways
1st Round 3rd Round
• Access to waterways some of the time
• At present stock may have access to waterways for periods of about a week about 4 times a year, same as the rest of the landscape
• Control when & how long cattle access the waterway, but not necessarily tied to the 'wet season'
• Have bore and trough set up to encourage cattle away from creek
• I control riparian as needed to maintain ground cover and stop erosion
• No permanent water in creeks; No permanent water in waterways
• Part of rotational strategies
• We manage cattle access to waterways
• Careful Rotation and Fencing and maintenance of ground cover
• Cattle access waterways for short graze periods no more than three times a year
• Depending on saturation event
• Encourage cattle to water troughs
• I don't entirely prevent them but I strategically place watering points away from the waterways so they don't congregate in the area, not permanent waterways. Do try to spell those areas throughout the wet season, not entire season but part of it, I guess that would be a help
• I use a combination. Some always, some never, some wet season spelling
• In the wet season all waterways excluded and in the dry season some waterways are excluded
• Management according to season; access on stable soils and riparian areas only; fencing off riparian areas for controlled grazing;
• Most creeks are fenced off with access to trough.
• Prevent cattle from accessing some water ways some of the time.
• Prevent cattle from accessing waterways at various times
• Rotate stock; too many waterways
• Spell paddocks including waterways
• We offer alternative troughs for the cattle to water from
• We have fenced cattle out of some water courses
• We prevent cattle accessing waterways as much as possible during the wet season
Advice land managers follow when making decisions about stock management around
waterways?
Land managers were asked to rank from 1= most important to 13=least important whose
advice they follow most when making decisions about stock management around waterways.
A cross tabulation between ‘advice land managers follow when managing stock around
waterways’ and ‘round of data collection’ compared responses from the first and third rounds
of data collection (see Tables 68 and 69).
In the first round of data collection, ‘other graziers’ was ranked as the most followed advisor
overall, by contrast ‘family who are also graziers’ was the highest ranked as most important
advisor. This was followed by ‘Other. Who?’ which included land managers own experience,
consultants, other successful graziers, grazing best practice and local council or authority that
is not a NRM, then ‘people from NQ Dry Tropics’, see Table 68.
99
Table 68: Advice Burdekin grazing land managers follow when making decisions about managing stock around waterways, ranked 1 most important to 13 least important – 1st Round Data Collection
Advisor 1st Round
Rank 1 2 3 4 5 6 7 8 9 10 11 12 13 Total
Other graziers 8 8 4 3 1 0 0 0 0 0 0 0 0 24
Other. Who? 15 2 4 1 0 0 0 0 0 0 0 1 23
Family who are also graziers 18 2 1 1 0 0 0 0 0 0 0 0 0 22
People from NQ Dry Tropics/TERRAIN 7 6 6 1 1 0 0 0 0 0 0 0 0 21
Researchers 3 3 4 1 0 1 0 0 0 0 0 0 0 12
Extension officers. From where? 2 2 3 3 0 1 0 0 0 0 0 0 0 11
Landcare 2 3 3 2 1 0 0 0 0 0 0 0 0 11
People from government departments. Which departments?
2 1 2 0 0 0 0 0 0 0 1 0 6
Meat & Livestock Australia 1 1 2 1 0 0 0 0 1 0 0 0 0 6
Private Agronomists 1 0 1 0 0 0 1 0 0 1 0 0 0 4
Non-farming family/friends 0 1 1 0 0 0 0 0 1 0 0 3
Agforce 0 0 1 0 0 0 1 0 0 0 0 0 0 2
QLD Farmers Federation 0 0 1 0 0 0 0 1 0 0 0 0 0 2
*Other. Who? (number of responses): their own experience (8); consultants e.g. Resource Consulting Services (5); trials/education programmes (1); other successful graziers (1); holistic management graziers/educators (1); grazing best practice (1); local council/authority, not NRM (1) **Other Extension, from where?: DAF (4); Department of Natural Resources (2); CSIRO (1); NQDT (1) ***Government Departments: DAF/DPI (2)
In the third round, ‘family who are also graziers’ were ranked both as the most important
advisor overall and as the most important advisor, followed by ‘other graziers’. ‘Other. Who?’
was ranked as the third most important advisor and included the land managers own
experience, consultants, trials and education programmes and industry representatives, see
Table 69.
Table 69: Advice Burdekin grazing land managers follow when making decisions about managing stock
around waterways, ranked 1 most important to 13 least important – 3rd Round Data Collection
Advisor 3rd Round
Rank 1 2 3 4 5 6 7 8 9 10 11 12 13 Total
Family who are also graziers 18 6 4 0 3 1 0 1 1 0 0 0 0 34
Other graziers 11 11 4 4 1 1 0 1 0 0 0 0 0 33
Other. Who? 25 3 0 0 0 0 0 0 0 0 1 0 1 30
People from NQ Dry Tropics/TERRAIN 6 8 6 4 1 1 2 0 2 0 0 0 0 30
Extension officers. From where? 3 3 2 3 2 1 0 1 0 1 1 1 0 18
People from government departments. Which departments?
0 3 6 0 0 0 1 0 0 1 1 3 2 17
Researchers 4 2 1 3 1 1 1 0 1 1 1 0 0 16
Meat & Livestock Australia 1 0 2 1 1 3 1 3 1 0 1 0 14
Agforce 0 1 1 3 1 2 0 1 0 1 0 2 0 12
Landcare 1 3 2 1 0 0 0 1 0 1 1 1 0 11
Private Agronomists 1 1 1 0 0 1 2 1 0 0 0 2 0 9
QLD Farmers Federation 0 0 0 0 1 1 1 0 0 1 1 1 1 7
Non-farming family/friends 0 0 1 0 0 0 0 0 1 1 0 2 1 6
*Other. Who? (number of responses): their own experience (15); consultants e.g. Resource Consulting Services (8); trials/education programmes (1); industry representatives (1) **Other Extension, from where?: DAF (7); credible environmental officers (1); NQDT (3); local industry representatives (1) ***Government Departments: DAF (6)
100
Attitudes and motivations associated with stock management around waterways
The next question asked participants how important a set of listed statements were to land
managers when making decisions about managing stock around waterways. The participants
were asked to choose the importance of each statement on a scale of 1-strongly disagree to
7 strongly agree, with 4 being neutral.
The first set of statements considered influencers when making decisions about adjusting
stocking rates. Burdekin graziers follow their chosen method for managing stock around
waterways because ‘the people/organisations whose advice they follow most think they should
do this’. There is a slightly lower agreeance in third round data (M=5.59, SD=2.03) compared
to first round data (M=5.10, SD=1.87). The data indicates land managers decisions about
managing stock around waterways are also somewhat influenced by ‘the graziers they respect
most think they should do it’ in both first (M=5.17, SD=1.80) and third round (M=5.28, SD=1.55)
data. First round data (M=4.26, SD=2.23) indicates that graziers held a neutral stance on the
statement ‘other graziers having the technical knowledge to implement current pasture spelling
practices’. However, in third round data (M=3.85, SD=2.08) collection they somewhat
disagreed with the statement, indicating they thought other land managers had the technical
knowledge to manage stock around waterways. Land managers were unsure if graziers could
not afford the systems being used for managing stock around waterways (first round M=4.09,
SD=2.28; third round M=4.01, SD=2.12) and they did not agree that they were being forced to
use the methods, see Table 70.
Table 70: Burdekin grazier land manager attitudes and motivations associated with stock management
around waterways
1st Round 3rd Round n Mean SD n Mean SD
The people/organisations whose advice I follow most think I should do this
54 5.59 2.03 68 5.10 1.87
The graziers I respect most think I should do this 54 5.17 1.80 68 5.28 1.55
Most graziers in this region would not have the technical knowledge to do this
54 4.26 2.23 68 3.85 2.08
Most graziers in this region would not be able to afford to do this 54 4.09 2.28 68 4.01 2.12
I only use this system to manage stock around waterways because I am forced to. Who/what is forcing you?*
54 3.48 2.64 68 2.38 2.02
Note: 1=strongly disagree, 7=strongly agree, *=significant at 5% level
An independent t-test highlighted a significant difference for ‘I only do this because I am forced
to. What or who is forcing you?’ score for first round (M=3.48, SD=2.64) and third round
(M=2.38, SD=2.02; t(120)=2.53, p=.01, two tailed). The magnitude of difference in the means
(mean difference =1.10, 95% CI: .24 to 1.96) was small to moderate (eta squared =.05). The
results show that while land managers indicated they are forced to manage stock around
waterways, it had decreased in importance between first round and third round data collection,
only .5% of the variance was explained by time between the data collection points. This may
be due to land manager’s lack of control of natural waterways, the number of waterways and
the financial means to manage waterways. There was no significant difference between the
other means across the two data collection periods.
While there were no anecdotal comments in the first round, the anecdotal comments from the
third round of data indicate that the force was coming from excessive natural waters, financial
burden and too many waterways to effectively manage, see Table 71.
101
Table 71: Anecdotal comments from Burdekin grazing land managers about who/what is forcing them to manage stock around waterways
1st Round 3rd Round
No comments
• Excessive natural waters
• Finances not enough money for fencing
• Financial
• Knowledge that it is very beneficial to the environment
• Too many waterways to effectively manage
• Too expensive to fence off every creek
The second set of statements asked the land manager to read the statement and respond how
using their method for managing stock around waterways measures when compared to other
ways of managing stock around waterways.
While all statements have high agreement (see Table 72) ‘the most effective way of controlling
erosion on my property’ and ‘the best way to meet my personal goals’ are the most agreed
with motivators for using the method that the land manager is using to manage stock around
waterways. Grazing land managers agreed that ‘the best way to maintain good cash flow’ and
‘the best way to reduce business risk’ were also considered when thinking about the system
they use for managing stock around waterways, or not, during the wet season. Being time
consuming or labour intensive were neutral to motivation to managing stock around
waterways.
Table 72: Compared to other ways of managing stock around waterways, what motivates Burdekin grazier
land managers to use the system that they use?
1st Round 3rd Round n Mean SD n Mean SD
The most effective way of controlling erosion on my property 54 5.69 1.66 68 5.19 1.61
The best way to meet my own personal goals 54 5.65 1.39 68 5.43 1.30
The best way to maintain good cash-flow* 54 5.56 1.54 68 4.85 1.43
The best way to reduce business risk 54 5.54 1.51 68 5.13 1.38
The least time-consuming (or labour intensive) 54 4.54 1.89 68 4.53 1.75
Note: 1=strongly disagree, 7=strongly agree, *=significant at 5% level
An independent t-test highlighted a significant difference for ‘the best way to maintain good
cash flow’ score for first round (M=5.56, SD=1.54) and third round (M=4.85, SD=1.43;
t(120)=2.61, p=.01, two tailed). The magnitude of difference in the means (mean difference
=.70, 95% CI: .17 to 1.24) was small to moderate (eta squared =.05). The results indicate that
while land managers agreed the way they managed stock around waterways was the best way
to maintain good cash flow, it had decreased in importance between first round and third round
data collection, only 0.5% of the variance was explained by time between the data collection
points. This may be due to land manager’s lack of financial means to manage waterways or it
may be associated with drought or other farming practices and warrants further investigation.
There was no significant difference between the other means across the two data collection
periods.
Has managing stock around waterway changed?
To establish whether there was a change in the way land managers manage stock around
waterways between first and third round data collection, a multiple response cross-tabulation
was performed using the land manager unique identification number to identify graziers in each
102
round of data collection (1=Grazier First Round and 3=Same Grazier Third Round). However,
the number of graziers who completed the survey in both rounds was too small to draw
conclusions from the analysis.
Other innovative practices for managing stock around waterways
Land managers were asked if they used any other innovative practices to manage stock
around waterways. Sixty three percent selected ‘yes’ that they thought they were using
innovative practices in first round data collection and 33.9% selected ‘yes’ in the third round.
However, when matching responses to the ABCD Framework, the practices used meet
conventional to best management practice expectations. A list of anecdotal comments from
land managers describing the practices are included in Appendix 5. Table 73 gives examples
of practices being used, matched to the ABCD Framework.
Table 73: Other innovative practices - anecdotal comments from Wet Tropics land managers, coded (see
Appendix 5 for examples)
Do you use any other innovative practices to manage nitrogen and/or run-off?
1st Round 3rd Round
n Percent n Percent
Yes 22 40.7 38 52.1
No 15 27.8 20 27.4
Other comments 17 31.5 15 20.5
Total 54 100 73 100
Coded Responses to Innovative Practices (see examples in Appendix 5)
ABCD Framework
1st Round 3rd Round
n Percent n Percent
Contouring banks C, B 2 12.5 1 7.1
Erosion Prevention Project B, A 6 37.5 4 28.6
Riparian Zone Management C 1 6.25 0 0.0
Maximum Pasture Management B 2 12.5 3 21.4
Gully Management B 2 12.5 2 14.3
Grazing Management Practices B 3 18.75 3 21.4
Fencing C, B 0 0.00 1 7.1
Nothing, stopped by GOV regulations D 0 0.00 1 7.1 Total 149 100 55 100
6.3.3.5 Perceptions of Causes and Pressure on Water Quality
Land managers were asked to agree (7) or disagree (1) with a statement about how nutrient
loss impacts water quality in local streams, rivers and waterways. They could also select that
they did not know or were unsure how local streams, rivers and waterways were impacted (8)
or neutral (4).
A means analysis shows that grazing land managers are taking measures to reduce soil loss
from their property to improve land conditions and they somewhat agree that soil loss from
their property negatively impacts their pasture production and grazing land condition.
Land managers also recognise that sediment loss from their property is having an impact on
water quality in local streams, rivers and waterways, see Table 78. An independent t-test
produced no significant difference in scores for each statement, highlighting that there has
been no change in land managers perceptions about soil loss between the first round and third
round of data collection.
103
Table 74: Means analysis of Burdekin grazing land managers to the statement about how soil loss impacts water quality from the Burdekin region
1st Round 3rd Round
n Mean SD n Mean SD
I am taking measures to reduce soil loss from my property and improve land conditions
53 6.42 0.77 73 6.49 0.84
Soil loss from my property negatively impacts my pasture production and grazing land condition
53 5.72 1.70 73 5.45 2.15
Sediment loss from my property has no impact on water quality in local streams, rivers & waterways
53 3.64 2.09 73 4.03 2.32
Note: 1=strongly disagree, 7=strongly agree, *=significant at 5% level
When asked what Burdekin grazing land managers thought were the top two causes of poor
water quality in local streams, rivers and waterways, they responded that the top cause in first
round data collection was erosion/sediment (15.2%) and vegetation/weed management
(15.2%) and the second top cause was poor land management (22.2%). In the third round of
data collection, erosion/sediment (12.9%) and lack of rain or irregular water flow (12.9%) were
identified as the top cause of poor water quality. By contrast, 12.9% identified as not having
poor water quality in their local streams, rivers and waterways as the first cause. The second
top cause identified in third round data collection was erosion/sediment (17.9%), see Appendix
10 for anecdotal land manager comments, which were coded into themes contained in Table
75.
Table 75: Burdekin grazing land managers two top causes of poor water quality in local streams, rivers
and water ways – Burdekin
1st Round 3rd Round
Cause 1 Cause 2 Cause 1 Cause 2 n Percent n Percent n Percent n Percent
Erosion/sediment 7 15.2 4 11.1 9 12.9 7 17.9
Vegetation/weed management 7 15.2 4 11.1 7 10.0 5 12.8
Lack of rain or irregular water flow 6 13.0 2 5.6 9 12.9 2 5.1
No poor water quality 4 8.7 0 0.0 9 12.9 0 0.0
Poor soil 3 8.7 0 0.0 0 0.0 1 2.6
Drought 3 6.5 4 11.1 3 4.3 1 2.6
No ground cover 3 6.5 2 5.6 5 7.1 3 7.7
Chemicals/contamination 2 4.3 3 8.3 2 2.9 1 2.6
Mining 2 4.3 1 2.8 3 4.3 1 2.6
Pollution and or rubbish 2 4.3 1 2.8 0 0.0 1 2.6
Poor grazing practices 8 4.3 0 0.0 5 7.1 5 12.8
Heavy rainfall or extreme weather 1 2.2 4 11.1 5 7.1 2 5.1
Feral animals 1 2.2 0 0.0 2 2.9 2 5.1
Main roads 1 2.2 0 0.0 1 1.4 1 2.6
Excessive use of fire 1 2.2 0 0.0 0 0.0 0 0.0
Poor land management 0 0.0 8 22.2 3 4.3 4 10.3
Don't Know/Other 1 0.0 1 2.8 4 5.7 0 0.0
Poor cane farming practices 0 0.0 1 2.8 1 1.4 0 0.0
Government/Legislation/Policy 0 0.0 1 2.8 0 0.0 0 0.0
Urban development 0 0.0 0 0.0 1 1.4 2 5.1
Run-off 0 0.0 0 0.0 1 1.4 1 2.6
Total 52 100 36 100 70 100 39 100
104
Next Burdekin grazing land managers were asked to strongly agree (7) or strongly disagree
(1) with a statement about the role that grazing plays in the declining health of the Great Barrier
Reef (GBR). Land managers could also select that they did not know or were unsure (8) or
neutral (4) about what role grazing plays in the declining health of the GBR.
A means analysis indicates that in both first round and third round data collection, land
managers held a neutral stance towards the statement “the grazing industry plays almost no
role in the declining health of the Great Barrier Reef”.
Table 76: Means analysis of Burdekin grazing land manager statement about the role cane growing plays
in the declining health of the Great Barrier Reef
1st Round 3rd Round
n Mean SD n Mean SD
The grazing industry plays almost no role in the declining health of the Great Barrier Reef
53 4.15 1.96 73 4.75 2.09
Note: 1=strongly disagree, 7=strongly agree, *=significant at 5% level
A frequency analysis of the same data (see Figure 7) shows less agreeance with the statement
in third round data collection than in first round data collection. This may indicate a change in
attitude towards the role that the grazing industry plays in the declining health of the Great
Barrier Reef by Burdekin cane farmers i.e. that graziers may play some role in the declining
health of the GBR.
Figure 7: Responses from Burdekin grazing land managers about the role grazing industry plays in the
declining health of the Great Barrier Reef
Burdekin grazing land managers were asked to write comments about what they thought the
two top pressures were on the GBR. Land manager responses were coded into themes, a full
list of anecdotal comments can be found in Appendix 11. In the first round of data collection
Burdekin graziers’ listed chemical run-off (18.9%) as the main pressure on the GBR. The
second top pressure was listed as land clearing/erosion/lack of ground cover (14.6%). In the
third round of data collection urban development/pollution (21.7%) was listed as the top
pressure and more so as the second top pressure (22.4%) on the GBR. Other pressures
0.0
5.0
10.0
15.0
20.0
25.0
Stronglydisagree
disagree Somewhatdisagree
Neutral Somewhatagree
Agree Stronglyagree
Do notknow/Not
sure
Perc
ent
The grazing industry plays almost no role in the declining health of the Great Barrier Reef
1st Round (n=53) 3rd Round (n=73)
105
include climate change, sediment, recreation and commercial fishing and natural processes.
These results support earlier findings (Farr et al., 2017d, p. 77) that grazing land managers
tend to shift the blame related to water quality and the health of the Great Barrier Reef rather
than consider their own practices as adding pressure to the GBR.
Table 77: Burdekin grazing land managers - two top pressures on the health of the Great Barrier Reef
1st Round 3rd Round
Pressure 1 Pressure 2 Pressure 1 Pressure 2 n Percent n Percent n Percent n Percent
Chemical Run-off 10 18.9 4 9.8 2 2.9 11 19.0
Climate Change/Global Warming
9 17.0 1 2.4 9 13.0 2 3.4
Urban Development/Pollution
8 15.1 5 12.2 15 21.7 13 22.4
Sediment 5 9.4 1 2.4 10 14.5 4 6.9
Don't know/Unsure 3 5.7 3 7.3 6 8.7 0 0.0
Natural Process 3 5.7 3 7.3 2 2.9 5 8.6
Coral Bleaching/Crown of Thorns
2 3.8 3 7.3 3 4.3 1 1.7
Inconsistent messages/knowledge
2 3.8 1 2.4 1 1.4 1 1.7
Tourism 2 3.8 0 0.0 0 0.0 2 3.4
Weather Events 2 3.8 0 0.0 6 8.7 0 0.0
Land clearing/Erosion/Lack of ground cover
1 1.9 6 14.6 1 1.4 2 3.4
Government 1 1.9 0 0.0 0 0.0 0 0.0
Mining 1 1.9 0 0.0 3 4.3 5 8.6
Other farming (not cane or grazing)
1 1.9 3 7.3 0 0.0 2 3.4
Pests/Weeds 1 1.9 2 4.9 0 0.0 0 0.0
Shipping/Boating Damage 1 1.9 1 2.4 1 1.4 2 3.4
United Nations/Greens Groups
1 1.9 2 4.9 0 0.0 0 0.0
Australian Defence Force 0 0.0 0 0.0 1 1.4 1 1.7
Nutrient Run-off 0 0.0 0 0.0 0 0.0 1 1.7
Other Run-off 0 0.0 1 2.4 2 2.9 2 3.4
Greenies/Do gooders 0 0.0 0 0.0 2 2.9 1 1.7
Sustainability 0 0.0 1 2.4 1 1.4 0 0.0
Recreational/Commercial Fishing
0 0.0 4 9.8 4 5.8 1 1.7
Lack of financial support 0 0 0 0.0 0 0 1 1.7
Minority Land Holders 0 0 0 0.0 0 0 1 1.7
Total 53 100 41 100 69 100 58 100
106
6.3.1.8 Grazing land managers results summary
This section has reported on results from questions related to nutrient and run-off management
practices in the dry tropics region of Queensland, Australia.
The results from the analysis confirm that grazing land managers in the Burdekin region goals
for their property are to create a sustainable and viable business to pass on to future
generations while improving pastures, groundcover and reducing weeds to increase
productivity. When making decisions to reach their goals, Burdekin grazing land managers
were primarily driven by maintaining the physical and mental health of their family. While
spending time with family, maintaining good relationships with other farmers and keeping in
contact with family and friends was also important, maintaining family traditions and heritage
was of neutral importance to decision making in the third round of data collection compared to
the first round.
Financially, grazing land manager decisions were influenced by minimising risk and
maximising profits as well as keeping a steady cash flow. Keeping farm costs low and reducing
debt were less important to decision making. Land managers indicated that ‘being able to
make their own decisions about their farm/property was the most important factor when making
decisions about what to do on the farm or property. Leaving the farm in better condition,
improving water supplies and minimising sediment run-off were all equally important to
decision making. Helping to safeguard native plants and animals and helping to safeguard the
GBR both increased in importance when making decisions about what to do on the farm or
property.
The data shows grazing land managers were spelling paddocks during the wet season and
that they were following the advice of family who are also graziers, their own experience,
consultants, and staff from the Department of Agriculture and Fisheries as well as other
farmers when making decisions about paddock spelling. While there was a slight decrease in
importance in third round, grazing land managers are implementing these practices because
the people or organisations whose advice they follow most, thinks that they should be
implementing these practices and also because the graziers they respect most are also
implementing the pasture practices, which increased in importance over the duration of the
study. This change reflects initial findings that found that graziers don’t make decisions in
isolation (see Farr et al., 2017d). Graziers were using their pasture spelling practice because
it was the best way to meet their own personal goals when managing pasture spelling.
We could not measure if there was a change in pasture spelling practices because not enough
land managers completed the survey in the first round and then again in the second round of
data collection.
The majority of grazing land manager respondents identified they were using other innovative
practices to manage stock around waterways. When matching responses to the ABCD
Framework, it was identified the practices being used met conventional to best management
practice expectations.
While grazing land managers were taking action to reduce soil loss from their property, they
were less certain that the soil loss had a negative impact on their pasture production and
107
grazing land condition by the third round of the study. Overall, recognition that sediment loss
has an impact on water quality moved from dis-agreeance to a neutral stance, but there was
no significant difference in grazing land managers perception over the duration of the study.
In the beginning of the survey period, land managers identified problems with water quality to
be caused by erosion and sediment, vegetation and weed management, and lack of rain or
irregular water flow in local streams, rivers, and waterways. By the end of the study, erosion
was equally identified with lack of rain or irregular water flow as a cause or poor water quality
in local streams, rivers, and waterways. By contrast, some grazing land managers highlighted
in the third round of data collection that they did not think that there was poor water quality in
local streams, rivers, and waterways. Others highlighted poor grazing practices and poor land
management as the second top cause of poor water quality in local streams, rivers, and
waterways.
Graziers in the Dry Tropics region held a neutral stance about grazing playing a role in the
declining health of the Great Barrier Reef. They identified the top pressures as being chemical
run-off, climate change or global warming and urban development at the beginning of the
study. In the final year of the study grazing land managers identified the pressure on the health
of the Great Barrier Reef to be mainly caused by urban development and pollution followed by
chemical run-off and climate change and global warming.
The estimates reported in Table 78 describe the impact of various predictors on the
consequents related to water quality behaviours, i.e. run-off behaviour and fertilizer application
behaviour. Results from the Wet Tropics region suggest that financial goals (β = -0.453, p <
0.05), technical knowledge (β = -0.219, p < 0.05) and labour extensiveness (β = -0.262, p <
0.05) are significantly linked with Run-off behaviour. The results related to fertilizer application
behaviour suggest that social goals are strongly linked with desired fertilizer application
behaviour (β = 0.279, p < 0.05). Similarly, the results from the Burdekin region suggest that
favourable fertilizer application behaviour can be shaped if focus is put on financial goals (β =
0.759, p < 0.05) as well as environmental goals (β = 0.725, p < 0.05). It can thus be suggested
that financial viability and environmental cause can have a positive influence on shaping
industry-specific standards in fertilizer application behaviour. Results linked with run-off
behaviours show that financial goals (β = -0.435, p < 0.05), environmental goals (β = -0.143,
p < 0.05), technical knowledge (β = -0.175, p < 0.05) and being forced to adopt run-off
behaviours (β = -0.155, p < 0.05) can be relied on to shape desired run-off behaviours in the
Burdekin region.
The results reported in Table 79 highlight how various theoretical constructs are linked with
individual goals. It is evident that in the Wet Tropics region lifestyle goals strongly affect
subjective norms for fertilizer application behaviour (β = 0.311, p < 0.05). However, for run-off
behaviours in the same region lifestyle goals are only linked with the attitude towards behaviour
(β = 0.600, p < 0.05). Results from the Burdekin region show social goals are linked with
attitude towards fertilizer application behaviour (β = 0.340, p < 0.05) as well as Run-off
behaviour (β = 0.358, p < 0.05).
108
Table 78: Estimates of Water Quality Behaviours
Predictors (X) Consequent Model Fit
Run-Off Behaviour – Cane Growers Wet Tropics region (n=105)
Run-off Behaviour Technical Knowledge Labour Extensive
Coefficient SE P Coefficient SE P Coefficient SE P Nagelkarke R2
Financial Goals -0.453 0.224 0.043 -0.106 0.154 0.945 0.108 0.128 0.399 0.164
Technical Knowledge -0.219 0.109 0.045 - - - - - -
Labour Extensive -0.262 0.143 0.067
Fertilizer Application Behaviour - Cane Growers Wet Tropics region (n=105)
Fertilizer Application Behaviour
Coefficient SE P Coefficient SE P Coefficient SE P Nagelkarke R2
Social Goals 0.279 0.112 0.014 - - - - - - 0.108
Fertilizer Application Behaviour – Cane Growers Burdekin Region (n=33)
Fertilizer Application Behaviour
Coefficient SE P Coefficient SE P Coefficient SE P Nagelkarke R2
Financial Goals 0.759 0.526 0.048 - - - - - - 0.169
Environmental Goals – Great
Barrier Reef
0.725 0.503 0.040 - - - - - - 0.191
Run-off Behaviour – Cane Growers Combined Burdekin and Wet Tropics (n=148)
Financial Goals – cost -0.435 0.207 .011 - - - - - - 0.153
Environmental Goals –
leaving farm in better
condition
-0.143 0.213 .047 - - - - - -
Run-off Technical Knowledge -0.175 0.095 .023 - - - - - -
Forced to adopt Run-off
Behaviour
-0.155 0.101 .0019 - - - - - -
109
Table 79: Relationship of Goals and TPB Constructs
Region Behaviour Predictor (X) Consequent Estimate P Status
Wet
Tropics
Fertilizer Application Behaviour Life Style Goals Subjective Norms 0.311 0.022 Supported
Attitude towards Behaviour 0.160 0.346 Not Supported
Financial Goals Subjective Norms -0.121 0.446 Not Supported
Attitude towards Behaviour 0.222 0.112 Not Supported
Social Goals Subjective Norms 0.274 0.083 Not Supported
Attitude towards Behaviour 0.045 0.831 Not Supported
Environmental Goals Subjective Norms -0.169 0.446 Not Supported
Attitude towards Behaviour -0.142 0.478 Not Supported
Run-off Behaviour Life Style Goals Subjective Norms 0.071 0.640 Not Supported
Attitude towards Behaviour 0.600 0.000 Supported
Financial Goals Subjective Norms 0.046 0.798 Not Supported
Attitude towards Behaviour -0.089 0.578 Not Supported
Social Goals Subjective Norms 0.231 0.137 Not Supported
Attitude towards Behaviour -0.088 0.500 Not Supported
Environmental Goals Subjective Norms -0.051 0.796 Not Supported
Attitude towards behaviour -0.301 0.078 Not Supported
Burdekin Fertilizer Application Behaviour Life Style Goals Subjective Norms 0.191 0.477 Not Supported
Attitude towards Behaviour 0.258 0.122 Not Supported
Financial Goals Subjective Norms -0.117 0.626 Not Supported
Attitude towards Behaviour -0.038 0.838 Not Supported
Social Goals Subjective Norms -0.151 0.573 Not Supported
Attitude towards Behaviour 0.340 0.036 Supported
Environmental Goals Subjective Norms 0.341 0.251 Not Supported
Attitude towards Behaviour -0.155 0.394 Not Supported
Run-off Behaviour Life Style Goals Subjective Norms 0.055 0.832 Not Supported
Attitude towards Behaviour 0.395 0.007 Supported
Financial Goals Subjective Norms -0.015 0.927 Not Supported
Attitude towards Behaviour -0.025 0.875 Not Supported
Social Goals Subjective Norms -0.322 0.232 Not Supported
Attitude towards Behaviour 0.358 0.050 Supported
Environmental Goals Subjective Norms 0.329 0.296 Not Supported
Attitude towards Behaviour -0.160 0.228 Not Supported
110
Additionally, we ran several models to explain the structure of the four goals (i.e. lifestyle goals,
financial goals, social goals and environmental goals) and their relationship with the constructs
of the theory of planned behaviour (reported through Figure 8 to Figure 11). The PLS SEM
approach was used to assess these relationships. The key advantages of PLS-SEM are that
it is more flexible to sample sizes and less sensitive to violation of multivariate data
assumptions (for instance, the normality of data) and provides equally reliable results without
compromising on the rigor and external validity (Faizan, Mostafa, Marko, M., & Kisang, 2018).
From the estimated model of fertilizer application behaviour in the Burdekin region (Figure 8)
it is evident that lifestyle goals are primarily driven by maintaining family traditions and heritage
(λ = 0.740), followed by the desire to spend face-to-face time with family and friends (λ =
0.720), maintaining physical and mental health of family (λ = 0.638) and maintaining good
relationships with other farmers / graziers in the local area (λ = 0.536). Financial goals were
found to be strongly affected by the intent of maximizing farm profits (λ = 0.852) followed by
the desire of minimizing the risk of very high costs or very low income (λ = 0.670) and servicing
debt (λ = 0.643). Social goals were mostly affected by the desire of sharing new ideas with
others (λ = 0.860) followed by learning about and testing new ways of doing things on
farm/property (λ = 0.789) and having efforts recognized by the wider community (λ = 0.562).
Finally, the environmental goals in the region, and for the behaviour, were primarily motivated
by the desire of helping to safeguard local waterways (λ = 0.846) followed by leaving the
land/farm in better condition than it was when the land manager first started managing it (λ =
0.783), minimizing sediment run-off and/or nutrient losses (λ = 0.705) and helping to safeguard
local waterways (λ = 0.544).
Figure 8: Run-off Behaviour - Cane Growers, Burdekin
111
From the estimated model of run-off behaviour in the Wet Tropics region (Figure 9), it is evident
lifestyle, financial goals and social goals were key factors associated with the constructs of the
TPB. Results reveal that lifestyle goals were primarily driven by the desire of maintaining good
relationships with other farmers/graziers in the local area (λ = 0.848) followed by maintaining
physical and mental health of family (λ = 0.837), keeping in contact with family and friends in
other ways (λ = 0.719) and maintaining family traditions and heritage (λ = 0.69). Financial goals
were motivated primarily by profit expectations (λ = 0.943) followed by desire of keeping a
stable (steady) cash-flow (λ = 0.904), keeping farm costs low (λ = 0.851) and minimizing the
risk of very high costs or very low income (λ = 0.826). Finally the social goals were found to be
primarily driven by the desire of learning about and testing new ways of doing things on the
farm/property (λ = 0.856) followed by sharing new ideas with others (λ = 0.820), having time
to pursue hobbies (λ = 0.583) and having efforts recognized by the wider community (λ =
0.582).
Figure 9: Run-off Behaviour - Cane Growers, Wet Tropics
112
The test for fertilizer application behaviour in the Burdekin (Figure 10) and the Wet Tropics
(Figure 11) regions shows how well each element of the goals is linked with its first order
construct.
From the estimated model of fertiliser application in the Burdekin region (Figure 10) it is evident
that lifestyle goals are strongly affected by traditions (λ = 0.740) followed by time spent on farm
(λ = 0.720), importance of health (λ = 0.638) and importance of relationships with other farmers
(λ = 0.536). Similarly, financial goals are primarily driven by profit motives (λ = 0.852), followed
by risk factors (λ = 0.670) and debt considerations (λ = 0.643). Social goals on the other hand
are primarily driven by farmers’ goals of sharing new ideas with others (λ = 0.860) followed by
learning about and testing new ways of doing things on the farm (λ = 0.789) and the desire of
having efforts recognized by wider community (λ = 0.562). Finally, environmental goals are
primarily driven by the desire of maintaining and improving water supplies and storages (λ =
0.846) followed by the objective of leaving the property/farm in better condition (λ = 0.783),
minimizing sediment run-off and/or nutrient losses (λ = 0.705) and helping to safeguard local
waterways (λ = 0.544).
Figure 10: Fertilizer Application Behaviour - Cane Growers, Burdekin
113
From the estimated model of fertilizer application behaviour in the Wet Tropics region (Figure
11) it is evident that lifestyle goals are strongly affected by the desire of maintaining good
relations with other farmers/graziers in the local area (λ = 0.905) followed by maintaining the
physical and mental health of family (λ = 0.756), keeping in contact with family and friends in
other ways (λ = 0.713) and by maintaining family traditions and heritage (λ = 0.717). Similarly,
financial goals were primarily driven by profit (λ = 0.929) followed by the desire of keeping a
stable (steady) cash-flow (λ = 0.902), minimizing the risk of very high costs or very low income
(λ = 0.888) and keeping farm costs low (λ = 0.827). Finally the third important set of goals in
the Wet Tropics region, and for fetilizer application behavior was social goals, which were
primarily driven by the desire to share new ideas with others (λ = 0.794) followed by learning
about and testing new ways of doing things on farm / property (λ = 0.738), having time to
pursue hobbies (λ = 0.684) and the desire of having efforts recognized by the wider community
(λ = 0.683).
Estimated models of Run-off behaviour in Burdekin (Figure 1) and Wet Tropics (Figure 3)
region show the estimates of elements for each goal associated with the constructs of the
theory of planned behaviour.
Figure 11: Fertilizer Application Behaviour: Cane Growers, Wet Tropics
114
It is important to note the high influence that networks have on land manager decisions, as
they may identify barrier to practice change. The findings support previous recommendations
for a land manager network analysis to ensure that information gatekeepers and opinion
leaders influence future water quality communication strategies (see Hay & Eagle, 2018).
A full list of recommendations from the third round of data collection can be found in Section
8.6.
See 5.3 Structural Equation Modelling.
115
RESPONSE TO RESEARCH OBJECTIVES
Consistent with a plea to determine ‘what works, for whom, in what circumstances and for
how long’ (Marteau et al., 2011, p. 264; Taylor, Pollard, Rocks, & Angus, 2012), this project
uses insights from the science of social marketing and behaviour change (see Eagle et al.,
2016) to implement (and test the efficacy of) changes to the marketing and engagement
strategy associated with programmes designed to be rolled out under the Reef 2050 Plan. It
aimed to change key behaviours to improve WQ. The following section addresses the main
objectives set prior to the beginning of the project.
7.1 Research Objective 1
Identify intrinsic and extrinsic motivations (motivations), value-orientations (values), norms,
‘habits’ (particularly relating to NRM), social networks and communication protocols of different
segments of land managers (particularly graziers and cane growers) in regions where WQ
improvement programmes have recently been, or will soon be, rolled out.
Land managers were asked about motivations, satisfaction, and reasons why they do things
for three different practices, calculating fertiliser rates, irrigation practices and handling run-off
for cane growers and spelling paddocks, stocking rates and managing stock around waterways
for graziers.
An individual’s values and stereotypes such as balance of work and lifestyle values, economic,
environmental and conservation values, self-transcendent, prosocial, altruistic and biospheric
values’ self-enhancement (i.e. hedonic, egoistic) values and biospheric concern were found to
be significant determinants of pro-environmental behaviour. Social predictors are likely to see
culture, tradition, and self-identity as significant positive determinants of pro- environmental
behaviour and information predictors include consulting practical advice, scientific advice, and
technical information. Financial benefits and training opportunities can also make pro-
environmental behaviour more attractive. Therefore, the research aimed to identify the
reasons why land managers were doing specific agricultural practices or not doing them, what
motivates them in these decisions, and whose advice is most important to land managers (for
a more in depth discussion on pro-environmental behaviour and its determinants, see (Farr et
al., 2017a).
The table below identifies motivations, values, habits, social networks and communications
protocols activated when making decisions about what to do on the land managers farm or
property. It also identifies norms surrounding calculating fertiliser rates for cane farmers and
adjusting stocking rates for graziers. The percentage shows how much the land managers
agreed with the factor when making decisions on their farm or property. These factors (and
others contained in this report and previously published interim reports, which can be found
here https://nesptropical.edu.au/index.php/round-2-projects/project-2-1-3/ ) may be
considered when communicating with land managers about decisions being made about water
quality management.
116
Table 80: Factors activated when making decisions about what to do on the land managers farm or property
Importance of factors when making decisions (Extremely Important or Essential)
Wet Tropics Cane
Growers
Burdekin Cane
Growers Burdekin Graziers
Intrinsic
Motivation Being able to make your own decisions (69%)
Being able to make your
own decisions (72%)
Being able to make your
own decisions (61%)
Extrinsic
Motivation Leaving the land/farm in better condition (69%)
Leaving the land/farm in better condition (67%)
Leaving the land/farm in better condition (74%)
Value-orientation
(values)
Physical & mental health of family (71.5%)
Physical & mental health of family (58%)
Physical & mental health of family (68%)
Norms The farmers I respect most use the practice I use to calculate fertiliser rates (60%)
The farmers I respect most use the practice I use to calculate fertiliser rates (61%)
The farmers I respect most use the practice I use to adjust stocking rates (69%)
Habits Minimising sediment run-off and/or nutrient losses (66%)
Minimising sediment run-off and/or nutrient losses (67%)
Minimising sediment run-off and/or nutrient losses (57%)
Social Networks Good relations with other Farmers / graziers (38%)
Good relations with other Farmers / graziers (28%)
Good relations with other Farmers / graziers (18%)
Communication
Protocols
Keeping in contact with family & friends in other ways (34%)
Keeping in contact with family & friends in other ways (26%)
Keeping in contact with family & friends in other ways (32%)
7.2 Research Objectives 2 & 5
Research Objective 2
Assess reactions of land managers to complexities of language, message framing and
communication channels (‘messaging’) used in the programmes, perceptions of barriers to and
potential enablers of adoption of these programmes, perceptions of ‘threats’ to personal
freedoms and ‘trust’ in the programme.
Research Objective 5
Work with those who are implementing new programmes to use insights from (1) – (4) above,
to suggest and, where appropriate, implement ‘live’ alterations to marketing and engagement
strategies, i.e. undertake adaptive alterations to those strategies to encourage participation
amongst those likely to be disinclined to participate.
While the reactions of land managers to complexities of language, message framing and
messaging was not directly assessed, the materials supporting the programmes themselves
were assessed through a documentary analysis and the results disseminated to the NRMs,
researchers and other interested stakeholders, particularly in sugar cane growing regions to
enact a change in the level of readability of those materials, and in turn, the land manager’s
understanding of the project objectives.
Insights from the project’s document readability analysis extended an understanding that
communication materials need to be delivered in a way that can be read by the target audience.
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These were incorporated by the Social Marketing@Griffith team for the Queensland
Government’s RP167C Sandy Creek Project: On farm change for water quality improvement.
Analytical techniques were shared with the Social Marketing@Griffith researchers and
improvements were made to communications materials. The RP167C project team reported
enhanced readability was achieved in the Mackay Area Productivity Services (MAPS)
communications (e.g. web sites, newsletters), by Farmacist, and in a report card from both the
State of Queensland and Healthy Rivers to Reef Partnership. The study involved both
engaged (those who actively collect water samples) and disengaged (those who are not
actively pursuing growing practice change) land managers.
Invitation to present a workshop with Reef Catchments (Mackay) – Better Connected
Training Workshop for agricultural extension July 2019
Note: The following overview has been extracted from the Reef Catchments project report with
permission.
A workshop funded by the Queensland Government Reef Water Quality Program was held for
those interested in communicating regularly with industry members and extension officers.
The workshop was attended by extension officers, agricultural trainees, agronomists,
government, local council and communications staff. Twenty one people registered to attend
this event, with 14 people actually attending on the day (absences were due to illness and
conflicting demands of the cane crushing season).
The full day's training covered a range of topics designed to increase extension and project
officer confidence when connecting, communicating and building relations with landholders.
The workshop covered a range of topics including understanding your audience, talking face-
to-face, developing relationships and trust, dealing with negative/hostile stakeholders (positive
deviants), identifying key influencers in participant’s agricultural community, talking with larger
groups and improving written communications.
Feedback from the Better Connected workshop was very positive (see feedback statement
below) with 92.8% of attendees rated the workshop ‘excellent’ or ‘good’ (57% excellent and
36% good), with 7% rating it ‘fair’.
"As someone new to the industry, I gained a good insight of different types of
relationships and issues present and how to deal with them. Very informative,
engaging and worthwhile.”
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As part of the feedback process, participants were asked to identify the communications issues
they commonly face in their extension roles. For extension officers and those working in the
sustainable agriculture/ NRM / Reef space communication and connection challenges / issues
were identified as:
• Lack of engagement from growers
• Reaching the growers / importance of channels – what is the best way to effectively reach the right people?; Reaching reticent growers – distrust
• Debate about agreed best practice e.g. regenerative ag vs precision ag
• Communicating to landholders, industry, general public, government… does it all need to be tailored?; Push back on regulations
• Speaking the farmers language
• Reef regulations – trying to help them to comply but being considered ‘pushing’ government ‘orders’
• Afraid to say the wrong thing
• Presenting ideas / methods when they are disagreed with or unwanted
• Mixed messages
• Identifying the influencers – how do we do this?
• Building relationships and trust
• Can be difficult meaningfully contacting landholders who are out on the land – hard to know who already knows whom
• Lack of consensus from within industry
• Distance
• Starting lines of communication
As part of the feedback process, participants were asked to identify the key points they would
take from the training – what jumped out?
• Importance of setting the tone in grower interactions – avoiding patronising them
• Awareness of SMOG indicator (readability indicator for written material)
• Trying to drill down to what landholder drivers are
• Understanding the influencer network
• Awareness of networks mong landholders and within geographic locations
• Interesting survey results – what farmers think and find important
• Biases/ beliefs – remember we are all different
• Learning how to share stories and motivations to connect
• Self-examination re: beliefs and how to overcome bias when dealing with farmers
• Communicating with large groups
• Conflict management / resistance
• Social network analysis x 2
• The fact that there is commercial / practical value in developing good relationships.
This is not just a warm and fuzzy area, but key to program success
• Importance of ensuring written material is simple and at the right level for the audience
• Knowing who to focus on building relationships with through social mapping
• Strategies to communicate with growers
• Social influence and the innovation model
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7.3 Research Objectives 3 & 4
Research Objective 3
Examine similarities and differences in (1) and (2) between the land managers who have (do),
and have not (do not), chosen (choose) to participate in the programmes.
Research Objective 4
Identify mismatches between the extrinsic incentives and marketing messages of evaluated
programmes and the motivations, values, norms, habits and communication protocols of both
participating and non-participating land managers.
Research objective 3 & 4 not met: the project was unable to engage land managers who have
not chosen to participate in the programmes as data from these individuals was not collected
by the two NRM organisations, both of which advised that they were unable to establish a
system whereby data could be obtained from this group.
Innovators / Positive Deviants
The project engaged in face-to-face conversations with stakeholders at different stages of the
project who shared some of their concerns about not being recognised as innovators and/or
environmental stewards, but rather as negative or disengaged land managers. As a result, we
recommend and encourage support for those land managers who have changed practice but
who are seen by their peers as ‘going against the norm’ (described in the literature as ‘positive
deviants’ (Pant & Hambly, 2009)).
Positive deviants need to be considered given the strength of comments from both cane
growers and graziers. Survey comments indicate that ‘farmers I respect’ (i.e. strong social
norms as part of farmer identity) is a stronger influence than wider community factors, and that
sharing new ideas is important (see the discussion of diffusion of innovation in Section 2.1 of
the literature review, particularly the issues of compatibility, trialability and observability (Eagle
et al., 2016b, p. 14)).
‘Positive deviants’ experiencing success are meeting their personal goals and expected
outcomes of a particular practice. Meeting personal goals and expected outcomes are beliefs
that are highlighted as important in the survey responses. Perceived control was also
highlighted as important. Therefore, efforts to promote best management practice clearly and
convincingly should demonstrate the ecological benefits, such as improving the environment
and enhancing land managers ability to participate in ecological conservation activities to meet
the perceived control behaviour. This suggests opportunities for extension officers to facilitate
group ‘social learning’ with land managers, to share ideas and to learn from and support each
other (Hermans, Klerkx, & Roep, 2015) as part of strategies for ‘persuasion by discussion’
(Scott, 2012, p. 64) and collective action (Blackstock, Ingram, Burton, Brown, & Slee, 2010),
(excerpt from Farr et al., 2016).
Better Connected
Best management practice programmes largely ignore ‘positive deviants’ seeing them as
disengaged. Disengaged or negative stakeholders choose not to engage or they actively
oppose information because they believe that it is either unnecessary or intrusive or they may
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not believe there is a problem in the first place (Trotter, 2015). When comparing responses
from land managers and extension officers, it was clear that extension was underestimating
the importance of safeguarding the surrounding environment to land managers (Hay & Eagle,
2018). When asked how important it was to safeguard the Great Barrier Reef when making
decisions about what to do on their property, 59% of land managers said it was extremely
important. By contrast, only 11% of extension officers thought this would be important to land
managers when making decisions (Hay & Eagle, 2018). To change the level of trust for the
land manager, stakeholders (especially extension officers) need to develop relationships.
Developing relationships and trust takes insight. Insight is the capacity to gain a deep
understanding of others (landholders) worlds, as it exists for them. Insight comes from
observations of people’s realities (for example farm processes, family traditions, financial
influence and norms), these observations trigger our beliefs about those realities, these
triggered beliefs inform our judgement and our judgement affects how we make sense of what
we are observing (adapted from Sanova, 2017). Biases and beliefs filter the information we
receive and can distort our interpretation of what we observe.
External beliefs are mostly unconscious, and they can become outdated especially when not
exposed to different ideas, cultures and rituals. Internal beliefs are those you have decided
that are true, they come from things like your upbringing and your past experiences – they can
be energizing or they can be limiting (Sanova, 2017).
The results of our study indicate that extension officer’s may have filtered the information they
received about land managers using their biases and beliefs, which distorted their
interpretation of what they had observed of the land manager’s decision influencers.
Misunderstanding the importance of decision influencers may have changed the way
messages were being sent and received (Hay & Eagle, 2018, p. 8), which may have
significantly affected the level of trust of messages about water quality and how land managers
process them.
When working with science, extension officer’s belief systems are upgraded in line with
research findings. If land managers are not keeping up then there becomes a disconnect in
beliefs and biases, which causes a barrier to communication. When communicating with land
managers, extension officers need to know their own biases and acknowledge them.
Becoming aware of one’s biases allows us to be aware of other people’s biases. Knowing the
disconnect between one’s biases is fundamental to establishing intentional communication
with land managers about best management WQ practices.
7.4 Research Objective 5
Research Objective 5
Work with those who are implementing new programmes to use insights from (1) – (4) above,
to suggest and, where appropriate, implement ‘live’ alterations to marketing and engagement
strategies, i.e. undertake adaptive alterations to those strategies to encourage participation
amongst those likely to be disinclined to participate.
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Alteration/improvement of a marketing strategy for one of the many WQ improvement
programmes scheduled for rollout in 2017
A document readability analysis was completed on three water quality programmes in the Wet
Tropics and Burdekin regions. The results have shown all three programmes to be written at
a similar level well above the recommended reading level of grade / year 9 (Carbone &
Zoellner, 2012; Kemp & Eagle, 2008). The documents associated with the Reef Programme
(Burdekin), with a SMOG score of 13, were slightly more readable than documents associated
with the Reef Trust Tender (Wet Tropics) (SMOG score of 17) or the Reef Programme
(Burdekin) (SMOG score of 18). As a result, stakeholders involved in water quality
management strategies, altered and improved programme material that was rolled out in 2017
(see Section 4.0 and Hay & Eagle (2016b) for more results from the readability study).
While stakeholders involved in the project altered or improved how they delivered their
marketing strategy for water quality programmes, the many ‘competing’, and, at times,
‘conflicting’, water quality activities (see Section 3.0 Confounding Factors) that have been
underway in both regions makes it difficult to separate out any one programme’s effects from
heightened awareness of effective communications, and issues such as readability in written
communication. However, there are good examples from water quality project teams who
have altered or improved their communications. Stakeholders and Project Managers supplied
the following summaries of how the research had influenced communications for their
programs as follows:
NQ Dry Tropics
“The NQ Dry Tropics “Connecting Cane Farmers to Their Local Wetlands” project has
been successfully trialling effective methods to increase sugarcane farmer adoption of
farm management practices to achieve reef water quality outcomes and improve the
ecological function of wetlands. The project created an engagement strategy based on
learnings from a literature review and a social study of barriers and benefits of practice
change. This strategy was updated annually based on a social monitoring, evaluation
and project adaptation framework. As a result, 13 of the 14 participants are now trialling
practice changes on their farms and the project team have a greater understanding of
what extension, education, engagement, and communication tools work best to
increase the benefits and decrease the barriers.
The NESP 2.1.3 and 3.1.3 projects played an important role in the successful delivery
of this project. The NESP project team reviewed the literature review, social study
questions, project fact sheets, information publications, and media releases, providing
useful input and insights for improvements. Their support helped us to improve the
readability of our communication products to ensure they were appropriate for the
target audience. Evaluations of these communication products showed that they were
well received and understood by the cane farmers and increased their understanding
and awareness of the subject matter (e.g. water quality issues for local wetlands and
the Great Barrier Reef).”
Laura Dunstan, NQ Dry Tropics, Program Manager, Waterways, Wetlands and Coasts
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Terrain NRM
“Terrain NRM is involved in a number of projects that aim to support farmers in making
practice change to improve water quality running off their farms. Given the subject
matter, many of the supporting communications products tend to be scientific or technical
in nature, which can make their readability challenging. The analysis provided to us by
the NESP {2.1.3 and 3.1.3] team gave us reassurance that we were pitching our
communications effectively at our target audience. In addition to giving us insights into
how previous communications products could have been improved, they also helped
inform the development of current materials by evaluating their readability and providing
ideas and suggestions on how to refine them further.”
Elaine Seager, Project Communications Leader, Terrain NRM
Behaviour Innovation
“Behaviour Innovation (BI) is a company that specialises in the design, delivery and
evaluation of population-level behaviour change programs. Project Cane Changer is BI’s
flagship project and has been successful at increasing sugarcane growers’ adoption of
Smartcane BMP, a program with strong links to water quality and environmental benefits.
BI has implemented behavioural skills training with extension officers and agronomists
as part of Cane to Creek and Project Uplift to improve the on-the-ground skillset of
extension staff.
The NESP 2.1.3 and 3.1.3 projects have provided a useful complement to the body of
work BI is currently undertaking. The underlying concepts of the NESP projects are to
understand the attitudes, behaviours, and barriers that landholders might have in terms
of how they engage with practice change and environmental initiatives (e.g., water quality
improvement). Both NESP projects have provided insights which are not only relevant to
the approach of Cane Changer but have informed other projects in the region that aim
to improve water quality and the health of the Great Barrier Reef.”
Dr John Pickering, Cane Changer Project Manager, Chief Behavioural Scientist at Behaviour
Innovation
The collaborative approach between the NESP TWQ Hub Project 2.1.3 team, NRMs, project
managers and others had a positive effect on behaviour change. The collaboration allowed
stakeholders to access the appropriate communication tools to implement them to improve
water quality projects.
7.5 Research Objective 6
Research Objective 6
Assess the efficacy of these interventions, determining if they result in changed behaviours
that are likely to generate more significant improvements in WQ than would otherwise occur.
Overall, there are positive indications that the water quality projects within the Wet Tropics and
Burdekin regions are generating significant improvements in water quality as evidenced by
comments from respondents to the survey and from feedback from project stakeholders.
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Results to date show that:
• farmers’ behaviour towards fertilizer application following the industry standards,
depends on elements of lifestyle (‘maintaining good relationships, with family, friends
and other farmers and maintaining family traditions’), social goals (‘learning about and
testing new things, sharing new ideas and making my own decisions’), and
environmental goals through subjective norms (‘farmers I respect most do this’).
• When handling run-off, the practice of using recycle pits was influenced by several
motivational factors through attitude towards behaviour (‘least time consuming and
reduce business risk’) and subjective norms (‘farmers I respect do this’).
• However, results for the use of recycle pits negatively mediated the impact, highlighting
that although farmers recognise using recycle pits as the desired run-off practice, it
may have been too time consuming and too risky for the business to adopt. These
findings may explain the poor uptake of desired practices for improved water quality.
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RECOMMENDATIONS AND CONCLUSION
8.1 Recommendations
The following recommendations have been drawn from each of the interim reports, which can
be found at the Reef and Rainforest Research Centre website https://www.rrrc.org.au/nesp-
twq-publications/
8.2 Recommendations Based on the Literature Review (Eagle et al.,
2016b)
There is a need to:
• Ensure all communication, by whatever means, sends consistent messages
irrespective of source, and channelling communication through trusted sources.
• Develop strategies for minimising the impact of competing and conflicting messages.
• Ensure that all persuasive communications are integrated in terms of key messages.
• Monitor media coverage and respond to inaccurate messages and develop proactive
media relationships.
• Incorporate social media strategies as part of an integrated communication strategy
that centres on the information channels and platforms used and preferred by land
managers. Review communication strategies, adding social media where appropriate,
recognising that this is likely to be most popular with younger land managers.
• Recognise the overall diversity of information sources and preferences.
• Incorporate long-term relationship management strategies based on customer
relationship management and business to business marketing concepts.
8.3 Recommendations Based on the Documentary Analysis of
Marketing Communications Material and subsequent
Communications Best Practice Guide (Hay & Eagle, 2016b,
2019)
The analysis has provided relevant material that should be considered when writing marketing
material for water quality programs and it has improved the understanding of the
communication components. However it is limited in its scope to provide users with guidelines
to produce quality communication material at the recommended reading level.
It is recommended that further research be completed to produce guidelines, templates and
readability assessment tools and message framing guidelines to support the fine tuning of
existing materials and the rollout of future communication material. During the analysis, it
became evident that there were limitations to the materials content imposed by various
government guidelines, which impacts heavily on readability. Therefore, it is important that the
outcomes of this analysis be used in discussions to inform stakeholders beyond the regional
natural resource management groups and others who supply the current programmes to land
managers.
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It is recommended that the Best Practice Guide for the development and modification of
programme communication material (Reference) be developed into a series of communication
workshops/webinars and/or an app/web based platform to accommodate numeracy and
literacy levels of the target audience. It was noted in feedback that the document was too long
and would not be useful. However, when presented to the Regional NRM Communication and
Engagement Officers Network workshop as a guide to writing marketing communications, the
attendees were excited that the guide could help them achieve the expectations of agricultural
marketing material to inform behaviour change in water quality management.
As noted in Hay and Eagle (2016), the choice of images used as part of communication has
significant impact on engagement. The link between imagery and communications framing
has been noted (Geise and Baden, 2015) but under-researched in the environmental context
(Hansen and Machin, 2013). It is suggested that the visual images that accompany news items
may increase misconceptions about the true nature of an issue (Ryu et al., 2013; Walters et
al., 2016). Further research should be carried out on the effects of visual imagery in the agri-
environmental context.
It is recommended that the following principles of design be followed:
• Ensure that the content provided is the most up to date and necessary information.
• The document is organised in a way that encourages all of the information be
consumed.
• That the credibility of the spokesperson be closely aligned with the message that is
being distributed.
• That text, layout and colour are used to meet the WCAG 2.0 level of contrast to a AA
or AAA standard.
• Visual imagery used must usefully add to the content.
• When including graphs and charts the Queensland Treasury guidelines will be used
http://www.qgso.qld.gov.au/about-statistics/presentation/presenting-stat-
infographs.pdf
• To find necessary and appropriate behaviour change solutions to water quality
challenges, it is important to develop ways of communicating the need for effective ‘buy
in’. Improving the way projects communicate and get buy in from producers will ensure
greater project uptake, associated results and lasting behaviour change.
8.4 Recommendations Based on First Round Descriptive Data
Analysis Wet Tropics and the Burdekin (Farr et al., 2017b,
2017c; Farr et al., 2017d)
This preliminary analysis of the first round of data within the Wet Tropics and NQ Dry Tropics
area revealed no ‘unexpected findings’ that run contrary to previous studies as outlined in our
2016 literature review (Eagle, Hay, & Farr, 2016). The responses from both cane growers and
graziers indicate that there is a reluctance to accept that their actions impact negatively on the
water quality of the Great Barrier Reef. Survey results show that cane growers were reluctant
to accept that nutrient loss from their property also has an impact on water quality in local
streams, rivers and waterways. Graziers, however, were more critical about their activities and
the role that sediment plays in reducing water quality. The results indicate that both groups,
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for each sector, have some tendency to shift blame to the other sectors (e.g. tourism, industry,
government, other farmers, shipping and fishing), and to see issues of water quality as due to
feral pigs in national parks and rainforest, soil run-off, river bank erosion, and erosion from
bare fallow and roads, residential or industrial activity as well as due to weather patterns and
climate change.
The recommendations that follow outline strategies that can be used to fine-tune existing
landholder interactions. Further explanation of the recommendations can be found in Farr et
al., (2016, pp. 53-64):
• There is a need to ‘sell the science’ to gain acceptance of the cause-effect relationship
between farming practice and water quality. NRM groups should work with
environmental science specialists to change views on the impact of farming practice
on water quality.
• There is a potential to extend the key role of extension officers in potentially influencing
increased uptake of BMP practices. There is a need to recognise the key role of
extension officers and determine what professional development support might be
beneficial in continuing to build trust and engagement with land managers.
• It is crucial to support innovation by celebrating success and sharing ideas. Land
managers should see their expertise is valued and their voices heard.
• Facilitate sharing of ideas and practices.
• Build on the role of farmers whose views are respected as information gatekeepers /
disseminators / role models.
• There is a need to ensure all communication, by whatever means, sends consistent
messages irrespective of source, and channelling communication through trusted
sources. Developing strategies for minimising the impact of competing and conflicting
messages.
• Ensure that all persuasive communications are integrated in terms of key messages.
• Monitor media coverage and respond to inaccurate messages and develop proactive
media relationships.
• Incorporate social media strategies as part of an integrated communication strategy
that centres on the information channels and platforms used and preferred by land
managers. Review communication strategies, adding social media where appropriate,
recognising that this is likely to be most popular with younger land managers. Need to
recognise the overall diversity of information sources and preferences.
• Incorporate long-term relationship management strategies based on customer
relationship management and business to business marketing concepts.
• Utilise Social Network Analysis to identify:
- key information gatekeepers / opinion leaders who may help or hinder
information dissemination and innovation uptake, and recognise social
relationships based on cultural / kinship factors.
- where individual extension officers may fit into various networks
• Recognise land manager diversity but use typology principles to develop material and
communication approaches to support extension officers in their interactions with
specific subsets of land managers.
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8.5 Recommendations Based on Second Round Data: Views from
Extension Officers (Hay & Eagle, 2018)
The key role of extension officers in interactions with Australian land mangers has been
recognized (see, for example, Ampt, Cross, Ross, & Howie, 2015; Vanclay, 2004). The
challenge now is to support extension officers at a regional level in their interactions,
particularly in difficult relationships with land managers who hold entrenched views regarding
the best practice for managing their own land. The following recommendations are made to
assist extension officers in their interactions with land managers.
Decision Making Factors
• Use social network analysis to identify information gatekeepers and opinion leaders.
The data indicates that extension officers may be underestimating the importance of decision
influencers, which can affect the way messages are communicated and hence influence
behaviour change.
Given the evidence that decisions are not generally made by one single individual and that the
views of ‘farmers I respect’ are important, we believe that there is value in considering the use
of Social Network Analysis (SNA). It is recommended that extension officers are trained in
social network analysis and that the analysis be applied to cane farmers and graziers in the
cane growing and grazing regions where there is the potential for identifiable individuals to play
a key role, positive or negative, in information dissemination. It is important that this training is
delivered through a consciously planned and facilitated delivery program rather than a self-
enrol, self-managed delivery.
SNA is a set of techniques used to analyse the social and informational contacts between
individuals with graphical representation (‘sociograms’) that use dots or circles to represent
individuals and lines to represent connections between them (Dempwolf & Lyles, 2012). The
following SNA is an example of a cane farming family located in the North Queensland region.
The value of SNA in the agri-environment context will lie in analysing the flow of information
and discussions, and in particular in identifying the extent of influence of key information
gatekeepers and opinion leaders who may have either power or influence over the adoption of
innovations. It overcomes the limitations of analysis based only on geographic proximity by
analysing social relationships that may be based on kinship or other factors. Advanced analysis
can identify the strength of ties or connections between individuals (Prell, Hubacek, & Reed,
2009), see a discussion of SNA in Farr et al., (2017b, p. 89).
The sociogram, which contains data provided to the researchers by a cane grower in the Wet
Tropics region of their own network (who has not had regular, recent official contact with
extension officers), shows that all of the individuals are connected in this network. In this
instance, the network maps shows both family and heritage ties, but may also show geographic
proximity as well. The cane farmer (1) is connected to eleven people in Group 1, but also to
the second cousin (13) who is connected to six people in Group 3. The cane farmer (1) is also
connected to Group 2 via another second cousin (20), who is connected to eleven people.
There is an indirect (weak) connection between second cousin (13) in Group 3 and the second
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cousin (20) in Group 2 via the uncle (18). While the second cousins (13 & 20) might know
each other they do not influence each other, but rather they both play a role in influencing the
uncle (20). The cane farmer (1), second cousin (13), second cousin (20) and the uncle (18)
may be identified in this farming family as the influencers. Therefore, it is important to identify
the key influencers in any social network, both as potential disseminators of information or
potential ‘blockers’ of practice change.
Figure 12: Social Network of a North Queensland Cane Farmer
Grants and Funding
The findings identify that an extension officer’s perception of the success or failure of an
application to a grant or funding may become a barrier for land managers to apply for funding.
Early adopters (Hay, 2018, pp. 109-112) have larger numbers of social contacts, which
influence the rate of adoption because of their role in those networks (Dowd et al., 2014).
However, ideas will only be taken up if there is a favourable attitude towards them, which
occurs when “others [extension officers] who he or she [land managers] have cause to trust
are considering it or have already adopted it” (Scott, 2012, p. 69). Thus, key influencers
(including extension officers) may act as a significant barrier to uptake of innovations (see the
discussion of diffusion of innovation in Eagle et al., 2016b, p. 15). It may also be useful for
extension officers to map networks for the land managers with whom they interact and to
consider their own roles within these networks.
• Recognise the key role of extension officers and determine what professional
development support might be beneficial in continuing to build trust and engagement
with land managers.
There is a contrast in the findings where extension officers believe they are cognisant of land
managers beliefs and land managers believe that their expertise and opinions are not valued
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and their ‘farmer voices’ are not being heard. In addition, innovation that is contrast to normal
growing practice, has been in the past actively discouraged. This contrast in understanding
may lead to scepticism regarding the need to change practice. Practice change requires
building a level of trust that is needed for positive long-term relationships (Eagle et al., 2016b,
Section 1.3). Therefore it is recommended that business coaching be used to help extension
officers to determine and receive professional development tools that might be beneficial to
increase their engagement with land managers. It is important that business coaching is
delivered through a consciously planned and facilitated delivery program rather than a self-
enrol, self-managed delivery.
Workshops, Training and Other Activities
• Recognise land manager diversity but use typology principles to develop material and
communication approaches to support extension officers.
• Build on the role of farmers whose views are respected as potential information
gatekeepers / disseminators / role models.
Extension officers and land managers both identified that workshops and training were
appropriate and useful. However, extension officers highlighted that best management
practice workshops need to be held outside of the harvest season, that they should target skills
deficiencies and be better coordinated with simpler processes (see Section 3.4). Land
managers highlighted that the instructors need to be more knowledgeable, that programs are
currently poorly targeted, and that people at the coal-face need to be more involved with the
development of training practices. Land managers also called for more tailored delivery of
programmes (see Farr et al., 2017b, pp. 49-59).
While the diversity of farmers and farming practice is acknowledged, it is useful to consider the
role of typologies in developing resources to aid extension officers in their interactions with
land managers through the identification of the range decision-making drivers and the types of
land managers who are motivated by similar drivers (Graymore, Schwarz, & Brownell, 2015).
Shrapnel and Davie’s (2001) five dominant personality styles may be used to direct learning
(Figure 13).
For example, the “vigilant personality” values autonomy, therefore, may prefer a one on one
approach to information gathering. Whereas the “solitary personality” feels comfortable alone,
and prefers not to deal with people at all, therefore may suit an online learning environment or
learning from trade magazines or television. The “serious personality” is not outgoing and
does not like to be told things and would value information sharing in educated groups. By
contrast, the “sensitive personality” is cautious when in groups and is stressed by unfamiliar
surrounds; therefore, they would learn better in small groups of familiar people, such as
extension staff (see Hay, 2018; Hay, Eagle, & Low, 2017).
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Figure 13: Farmer Typologies and Learning Preferences
We recommend that training programs be coordinated with land manager representatives of
cane growing and grazing in the regions. We further recommend that training programs are
themed towards the currently identified skills deficiency and that programs are developed
towards best management practice and conducted outside of the harvest season. The final
recommendation is to use the farmer typology and learning preferences to deliver training
programs.
Perceptions of Causes and Pressure on Water Quality
• Ensure all communication, by whatever means, sends consistent messages
irrespective of source, and channelling communication through trusted sources.
• Monitor media coverage and respond to inaccurate messages and develop proactive
media relationships.
• Review communication strategies, adding social media where appropriate. Need to
recognise the overall diversity of information sources and preferences.
• Proactive plans should be developed for combating or at least minimising the effects
of competing and conflicting messages including negative media coverage (see Eagle
et al., 2016, Section 2.7). We have reviewed media coverage of the Great Barrier Reef
during 2016 (excluding tourism-related coverage). The findings indicate that the media
presents a sensationalised and, at times, hostile perspective on reef-related issues
(Eagle et al., 2018), although there was evidence that this was improving in the 2017
media analysis.
There are a range of competing and conflicting messages received by land managers,
including largely negative media coverage of issues relating to the health of the Great Barrier
Reef, and messages from mills and farm supply merchants. We note that information overload
appears to be an irritating factor for some land managers and recommend that a system be
131
set up to monitor information from all sources and to combat messages that run counter to the
desired core messages re: BMP.
We recommend that consistent messages be sent, irrespective of the source with key
informants being involved in message design and delivery where possible. Ideally this would
be as part of an integrated communications strategy (Dahl, Eagle, & Low, 2015), using a
combination of both traditional and digital media (Batra & Keller, 2016; Keller, 2016) that
encompasses federal, state and local-originated material and encompassed all forms of
communication, whether print, electronic or face-to-face advice as part of this integration.
We note, however, that there is widespread distrust of government-originated information,
therefore the source of information must be considered, along with the readability issues
identified in our earlier report (Hay & Eagle, 2016) and also the communication channels
preferred by land managers.
8.6 Recommendations Based on Third Round Data. Final Report:
Findings from a longitudinal study of farmer decision
influencers for Best Management Practices (Hay & Eagle, 2019)
The comparative analysis between first round and third round wet tropics and dry tropics data
revealed small but positive changes in water quality management behaviour in both regions.
There is a need to recognise the good work that land managers are doing to improve water
quality. While, wet tropics cane growers identified ‘having efforts recognised by the wider
community’ as important, cane growers in the Burdekin identified ‘learning about and testing
new ways of doing things on your farm/property’ as important. Graziers on the other hand
highlighted ‘having time to pursue hobbies’ as important. All three groups highlighted
extension officers, family, and other graziers/growers as important to decision making.
Recognising the difference in personality between cane farmers, graziers, and regions is
important in developing resources to aid and extend increased uptake of BMP practices.
Therefore, we reiterate the following recommendations:
• There is a need to recognise the key role that extension officers play in facilitation and
sharing ideas with farmers and to determine what professional development support
might be beneficial in continuing to build trust and engagement with land managers.
• It is crucial to support innovation by celebrating success and sharing ideas. Land
managers should see their expertise is valued and their voices heard.
• Facilitate the sharing of ideas and practices
• Building on the role of farms whose views are respected as information gatekeepers /
disseminators / role models.
• Recognise land manager diversity but use typology principles to develop material and
communication approaches to support extension officers in their interactions with
specific subsets of land managers.
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8.7 Recommendations based on Data Collection and Analysis
It is recommended that data be collected using a longitudinal omnibus survey method, where
data on a wide variety of subjects is collected during each phase of data collection, similar to
Census data. Multiple clients or stakeholders can share the cost of conducting the research.
Experiments can be timed to better suit cane growing and grazing practices to encourage
participation. This may mean reducing the number of projects that are funded into the regions
and concentrating more on repeating specific experiments over time to increase the reliability
of the data. In addition, interventions or programmes in each region of the Great Barrier Reef
Basin should follow a defined theme (i.e. one theme per funding round) so as to increase the
measurability of theme specific interventions overall. In turn, other negative factors including
survey fatigue and confusion caused by conflicting findings may then be reduced.
While the data was analysed using structural equation modelling (SEM), the findings are
superficial due to theoretical and methodological gaps in the TPB model (see Section 5.3 for
further explanation). The SEM measured wet tropics cane growers only and highlights positive
influence of environmental goals on fertiliser application through lifestyle and social goals as
well as ‘farmers I respect most do this’. These findings are supported by the descriptive
analysis contained in the third round results in Section 6.3. While the findings are positive,
interesting, and relevant, it is recommended:
• That the data be further analysed by an expert data analyst alongside expert extension
staff to gain a deeper understanding of the findings from the expert extension
perspective to drill into the data to determine the depth of behaviour change.
• If the study is to be repeated, expert extension knowledge should be used to refine the
questionnaire to maximise its utility to the extension community.
8.8 Conclusion
Cane growers in the Wet Tropics region have changed the way they calculate fertiliser
application rates positively towards best management practices. For run-off practices, while
the data indicates changes in the way that cane growers in the wet tropics are handling run-
off, the results cannot determine if land managers are using best practice management
techniques to handle run-off or some other method. Where previously, the wet tropics cane
growers held a neutral stance that their industry plays a role in the declining health of the GBR,
there is higher agreeance from wet tropics cane farmers about their industry’s role in the
declining health of the GBR. However, there still exists a tendency for wet tropics cane growers
to shift the blame related to water quality and the health of the Great Barrier Reef to other
organisations, industries, and individuals rather than consider their own practices as adding
pressure to the GBR.
While cane growers in the Burdekin region have also changed the way they calculate fertiliser
application rates positively towards best management practices. Less reported using industry
standard rates in the final round of data collection (there has been an increase in the use of
advisors and agronomists and the decision being dependent on cash flow, ground water,
experience and budget has been highlighted, which may offer some explanation). While there
have been changes in the tools that Burdekin cane growers are using to manage irrigation and
to handle run-off, the results cannot determine if land managers are using best practice
133
management techniques for managing irrigation or handling run-off or some other method.
Burdekin cane growers still hold a neutral view about whether or not nutrient loss from their
property has an impact on water quality in local streams, rivers, or waterways. By contrast,
there is more recognition from Burdekin cane growers that cane growing plays some role in
the declining health of the GBR. However, similar to wet tropics cane growers, Burdekin cane
growers tend to shift the blame related to water quality and the health of the Great Barrier Reef
to other organisations, industries, and individuals rather than consider their own practices as
adding pressure to the GBR.
The results from the Burdekin graziers data is less clear. While there was not enough data to
compare the same grazier in 2016 to 2018 to establish if there had been a change in practices,
(i.e. different graziers completed the survey in the first round and the third round of data
collection) the results were fairly positive in terms of best management practice behaviour in
drought conditions. The majority of graziers who responded to the survey were using best
management and innovative practices that met the C/B, B, B/A criteria of the ABCD
Framework, with the majority of graziers planning to do the same into the future. At the end of
the study, there was higher agreeance that sediment loss from graziers’ property was having
an impact on water quality in local streams, rivers, and waterways compared to the beginning
of the study and the graziers stance on their industry playing a role in the decline of the GBR
moved from neutral towards agreement with the statement.
Expected Outcomes
The following expected outcomes were developed at the beginning of the program:
1) WQ improvement programmes that are designed (and marketed) in ways that better match
the motivations and values of land managers in the GBR.
2) Greater uptake/adoption of WQ improvement programmes with greater associated
changes in behaviour; thus a greater return on investment.
A change in language used in marketing material surrounding reef water quality was identified
in second round analysis. Since then the project team has assisted NRMs and other
stakeholders to review and alter their marketing communications to meet the
recommendations.
The readability study and results combined with the best practice guide that was developed
were adopted by both Terrain NRM and NQ Dry Tropics NRM to implement ‘live’ alterations to
marketing and engagement strategies throughout the duration (and after) of the project to
successfully engage with land managers. The alterations resulted in a greater uptake of water
quality improvement programs in the NQ Dry Tropics region as evidenced in Section 7.4. The
data analysis from the wet tropics shows incremental behaviour change in water quality
management, which may evidence expected outcomes 1 and 2 to have been met.
3) Insights about land managers and ways to tailor programmes to increase adoption that are
transferrable to other contexts.
Land managers and extension officers have indicated that holding workshops, training and
other activities outside of the harvest season, targeting skills deficiency, and better-coordinated
134
systems would make the activities work better for land managers. Tailoring programs to
improving land and soil management practices to raise awareness of water quality issues as
well as accreditation and networking was highlighted as important to land managers. Nutrient
management, soil chemistry, more involvement with extension officers and strategic
coordinated extension programs with assistance from the DES would help in future to assist
land managers to make farm improvements.
4) Insights into ways of measuring the ‘impact’ of interventions that are transferrable to other
contexts.
It is apparent that there will always be confounding factors that will impact the measurement
of any interventions actioned. As mentioned there are a multitude of competing and at times
conflicting activities that are underway in both the Wet and Dry Tropics regions to improve
water quality (see Section 3.0). It may be possible to subject research programs to themes in
set periods so as to incorporate all programs surrounding one theme as a single intervention,
which can then be measured for impact.
We also note a significantly increased level of media activity regarding the health of the Great
Barrier Reef in 2017 compared to 2016, particularly as a result of two consecutive years of
coral bleaching and a number of conflicting reports regarding the extent and consequences of
this. In 2016, 242 relevant media items were analysed. In the period January – June 2017
alone, 743 items were collected for analysis. Given that the first round of data collection
showed a high percentage of land managers did not believe their practices had any effect on
the health of the Great Barrier Reef, this increased coverage is likely to reinforce and possibly
even increase the land mangers’ existing perceptions. This issue needs to be addressed as
a matter of some urgency but is beyond the scope of this project.
It has been of concern throughout this project that some extension officers regard this project,
and the data obtained from it, as purely an academic exercise rather than having any
substantial relevance to their own activity. It was also noted that some extension officers have
shown themselves to be resistant to change, while others feel that any form of innovation is
actively discouraged by their organisations, resulting in significant levels of disillusionment
among these staff. The relevance of the findings detailed in this and preceding reports should
therefore be discussed with extension officers, with the discussion led by someone from within
their own community who has the necessary skills. This individual can thus help shape the
behaviour change within the relevant NRMs and other organisations that is necessary before
behaviour change can be expected from land managers who are not fully committed to best
land management practices. This should lead to co-creation, and thus stronger buy-in, from
extension officers (and others) to the recommendations made in the reports provided for this
project.
Upskilling of all relevant personnel (not just extension officers) is recommended in:
• The value of the application of relevant theory and communication frameworks to
practice.
• The benefits of a social marketing approach to behaviour change initiatives (see the
extensive discussion in the initial reports already provided for this project).
• The use of a range of social media platforms to communicate to stakeholders, and the
importance of visual imagery in reinforcing key messages.
135
Given that the challenges noted in this report are not unique to the two participating NRMs,
and the recommendations made in this report have application well beyond the two NRM
areas, an upskilling program could be developed by the regional university, using digital
platforms to deliver the program to a wide range of participants.
136
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APPENDIX 1: OVERVIEW OF SEM AND SUMMARY OF
MEASUREMENT ITEMS
The development of the SEM goes back to the early 1920s (Wright, 1921) and was expanded
in the 1940s to provide methodology where a combination of cause-effect information and
statistical data could be used to answer policy related questions (Haavelmo, 1943). The SEM
was further modified later in the century (Pearl, 1997) with refinements continuing into the
current century (Pearl, 2003).
SEM is based on simple regression equations which are linear in parameters and which form
a unified framework (Weis & Axhausen, 2009) but it is fundamentally different from a
regression model. In a regression model there is a clear distinction between the dependent
variable and independent variables. In SEM “such concepts only apply in relative terms since
a dependent variable in one model equation can become an independent variable in other
components of the SEM system” (Gunzler et al., 2013, p. 390).
A complete SEM contains the structural and the measurement equations. Those equations are
defined by ‘structural equations, measurement equations for endogenous variables, and
measurement equations for exogenous variables’ (Sharmeen, Arentze, & Timmermans, 2014,
p. 164). “Exogenous variables are always independent variables in the SEM equations’ while
endogenous variables can act as a dependent variable in ‘at least one of the SEM
equations...and may become independent variables in other equations” within the SEM system
of equations (Gunzler et al., 2013, p. 390).
Endogenous and exogenous variables can best be explained by a hypothetical example,
for example when modelling fishing, the number/frequency of reef fishing trips would be
classed as the dependent variable; as it depends on other variables including, boat
ownership (boat owners are more likely to fish on the reef more often), and being male
(males are more likely to go fishing more often). However, the influence of variables on
each other may go both ways. Boat ownership, can be influenced by a willingness to fish
on the reef and also by the frequency of fishing trips to the reef. Individuals who are willing
to go fishing on the reef more frequently would be more likely to buy a boat to go fishing.
As such, the boat ownership explains the number of reef fishing trips (the dependent
variable) and the number of reef fishing trips explains the boat ownership. Therefore, the
boat ownership, in this case, is endogenous. Put simply, boat ownership explains, but is
also explained by the frequency of fishing trips. Whereas being male (exogenous variable)
only explains the frequency of fishing trips and is not explained by the frequency of reef
fishing trips.
The measurement equations within the SEM are used to specify an unobserved (latent)
variables “as a linear function of other variables in the system” (Jahanshahi & Hall, 2013, p.
17). If those independent (explanatory) variables in a linear function are observed they are
used as indicators of the latent variable. Factor analysis is often used to guide building of the
measurement equations (Jahanshahi & Hall, 2013). SEM allows modelling and testing of the
effects of all exogenous variables on all endogenous variables simultaneously or sequentially,
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and also “to account for both error correlations and direct effects between the endogenous
variables’ at the same time (Weis & Axhausen, 2009, p. 3).
In SEM the arrows indicate paths that connect variables. “When a path points from one variable
to another, it means that the first variable affects the second” (Statacorp, 2013, p. 7) (e.g.
attitudes towards spelling paddocks depend on behavioural beliefs that it will improve land
condition and will increase profits, Figure 15). The SEM approach can also measure the path
relationships (the path diagrams show the relationships between the variables in SEM) within
the TPB and indicate the relative significance of the paths between variables in the model
(Deng et al., 2016; Molenaar, Washington, & Diekmann, 2000). This approach has also an
ability to separate direct (direct influence of one variable on the other) and indirect (mediation)
effects. A simple model with one mediator is shown in Figure 14.
Figure 14: Simple statistical model with one mediator
An indirect effect is “the effects along the paths between the two variables through one or more
intervening variables” (Jahanshahi & Hall, 2013, p. 17), which are often called mediator
variables. Mediator variables are variables that “sit between the independent variable and
dependent variable and mediate the effect” of the independent variable on the dependent
variable (UCLA Statistical Consulting Group, 2017). The idea behind the analysis of mediation
is that some of the effect of the independent variable is transmitted to the dependent variable
through the mediator variable (Figure 14 path a and b). That portion of the effect that
transmitted from the independent variable through the mediator is the indirect or mediation
effect. Some portion of the effect of the independent variable goes directly to the dependent
variable (Figure 14 path c and c’) which is a direct effect (Adams & Boscarino, 2011). SEM
also allows one to estimate the total effect by summing indirect and direct effects between two
variables (Byrne, 2016; Jahanshahi & Hall, 2013).
A simplified multilevel SEM based on the TPB is shown in the Figure 15. Boxes are observed
variables with variable names written inside them (e.g. attitudes towards spelling paddocks,
farm size). Measurement errors for each variable are given in circles at the bottom (e.1, e.2,
e.3 etc.). Numbers next to the arrows are simultaneously/sequentially estimated coefficients
and one star (10% level), two stars (5% level) and three stars (1% level) correspond to the
statistical significance of the coefficient (e.g. estimated coefficient of perceived profitability
0.42** is positive and statistically significant at 5% level).
Independent variable
Dependent variable
Mediator variable
c
Without mediator
Independent variable
Dependent variable
With mediator
C’
a b
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Figure 15: An example for simplified multilevel linear SEM based on the TPB
Attitudes towards spelling paddocks, for example, have indirect (mediated by intention)
positive significant impact on actual behaviour. Actual control has a direct positive significant
impact on actual behaviour (the estimated coefficient 0.28*** is positive and statistically
significant at the 1% level of significance) implying that land managers who have actual control
over their own capital and skills are more likely to perform actual behaviour (spell paddocks
during the wet season) than those who do not (Figure 15). Perceived profitability is indirectly
positively influencing behaviour through behavioural beliefs and attitudes towards spelling
paddocks. However, looking at the magnitudes of the coefficient estimates (Figure 15),
attitudes towards spelling paddock (estimated coefficient 0.44**) have the strongest direct
impact on intentions to spell paddocks followed by subjective norms (0.1**) while perceived
behaviour control (estimated coefficient 0.82 which is not statistically significant) does not have
any direct significant impact on intentions.
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The structural equation approach ‘‘assumes a direct causal relationships between certain
dependent variables, and thus goes further than merely capturing these relationships via error
correlations” (Weis & Axhausen, 2009, p. 17). The assumptions associated with SEM that
ideally should be met to increase reliability of the results have been defined (Brain, 2008):
• all indicators in the model should be normally distributed (If this assumption is met, ‘the
variance of the estimated parameters is consistently estimated by sample variances,
but when it is not met, the standard errors of parameter estimates can be substantially
underestimated, leading to false conclusions of significance’ (Bagley & Mokhtarian,
2002, p. 286; West, Finch, & Curran, 1995).
• latent variables should be measured by multiple indicators (variables)
• appropriate data imputation
• adequate model fit
• large sample size
However in practice, meeting these conditions is problematic (Bagley & Mokhtarian, 2002) and
the normality assumption is often violated (Bentler & Dudgeon, 1996). Micceri (1898) reviewed
various journal articles and datasets used in those studies within the SEM and found that in
the majority of studies the conclusions were drawn from non-normally distributed data.
(Breckler, 1990) and (Gierl & Mulvenon, 1995) also noted that it is very common for the
researchers just “to ignore the assumption of normality and to make conclusions as if the
assumption were met” (Bagley & Mokhtarian, p.286).
SEM is ‘fundamentally a hypothesis testing method (i.e., a confirmatory approach), rather than
an exploratory approach (e.g., regression analyses)’ (Adams & Boscarino, 2011, p. 62). It has
some advantages over other statistical models that are linear in parameters (Adams &
Boscarino, 2011; Jahanshahi & Hall, 2013) (Golob, 2001) (e.g. hierarchical linear models such
as random regression, linear mixed-effects, and multilevel model). SEM has a more and much
broader “interpretable array of measures of overall model fit, more flexible modelling of residual
structures and of growth functions (e.g., typically, some slope loadings can be freely estimated
parameters), and a better overall capacity to model latent variables and their multivariate
associations” (Curran, 2003; Tomarken & Waller, 2005, p. 38).
SEM allows:
• a series of regression equations being estimated simultaneously to control for how
accurately the proposed model replicates the data (Byrne, 2010; Kline, 2010).
• ‘treatment of both exogenous and endogenous variables as random variables that may
exhibit errors of measurement’ (Jahanshahi & Hall, 2013, p. 17).
• ‘accounting for the reciprocal influences of the endogenous variables on one another’
(Weis & Axhausen, 2009).
• Incorporation of observed (directly measured) and latent variables (Byrne, 2010; Kline,
2010).
• Latent (unobservable variables) can be modelled with multiple indicators.
• Separating of measurement and specification errors.
• Ability to test whole structural model and each coefficient individually.
• Modelling and testing mediating variables (mediators) and their effects.
• Ability to handle non-normal data as well as categorical variables.
• Ability to model and control for error term relationships.
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Technical Foundations for Data Analysis: As TPB requires analysis of direct and indirect
relationships of its constructs, the choice of analysis technique considers the approaches that
provide analysis of both direct and indirect effects. Of the methods for analysing indirect
(mediation) effects in behavioural theories, the approach of Baron and Kenny (1986) is the
most frequently used (MacKinnon, Fairchild, & Fritz, 2007). As the outcome variable consisted
of binary measurement, this study referred to the approach used by Desislava and Matilda
(2011) for analysis of mediation effects with binary outcomes. The PROCESS macro for SPSS
v 24.0 (Preacher and Hayes, 2004) was used in SPSS to analyse direct and indirect effects,
which is very convenient and specifically appropriate when explanatory latent constructs are
based on a single item (Preacher & Hayes, 2004a). The model estimation was performed by
using Model No. 4 of Hayes’ templates (Preacher et al., 2007) that provides estimates of
indirect effects on the basis of upper and lower limit of confidence intervals, thus
accommodating the traditional limitation of the power problem in Baron and Kenny’s (1986)
approach. To assess the statistical significance of the estimated paths, 5000 bootstrap re-
sample and bias-corrected 95% confidence intervals (CI) were utilized (Preacher & Hayes,
2004b).
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149
APPENDIX 2: INDEPENDENT SAMPLES T-TEST (SECTION 5.3.1)
Levene's Test for Equality
of Variances
t-test
for Equality
of Means
95% CI
F Sig. t df Sig.
(2-tailed)
Mean Diff
Std. Error Diff
Lower Upper
Maintaining physical and mental health of family
Equal variances assumed 3.055 0.081 1.466 315 0.144 0.181 0.123 -0.062 0.424
Equal variances not assumed
1.288 96.58 0.201 0.181 0.141 -0.098 0.460
Maintaining family traditions and heritage
Equal variances assumed 2.474 0.117 2.085 314 0.038 0.377 0.181 0.021 0.733
Equal variances not assumed
1.948 103.8 0.054 0.377 0.194 -0.007 0.761
Spending face-to-face time with family and friends
Equal variances assumed 0.027 0.869 0.545 315 0.586 0.074 0.136 -0.194 0.343
Equal variances not assumed
0.547 114.0 0.586 0.074 0.136 -0.195 0.344
Keeping in contact with family and friends in other ways (e.g. via phone, through social media)
Equal variances assumed 0.202 0.654 1.837 312 0.067 0.329 0.179 -0.023 0.682
Equal variances not assumed
1.904 120.5 0.059 0.329 0.173 -0.013 0.672
Maintaining good relations with other farmers/graziers in the local area
Equal variances assumed 1.682 0.196 2.336 315 0.020 0.289 0.124 0.046 0.533
Equal variances not assumed
2.115 99.8 0.037 0.289 0.137 0.018 0.560
Keeping farm costs low
Equal variances assumed 0.253 0.616 0.391 315 0.696 0.051 0.129 -0.204 0.305
Equal variances not assumed
0.382 110.1 0.703 0.051 0.132 -0.212 0.313
Keeping a stable (steady) cash-flow
Equal variances assumed 0.429 0.513 0.043 315 0.966 0.005 0.113 -0.218 0.228
Equal variances not assumed
0.046 128.2 0.963 0.005 0.105 -0.203 0.213
Maximising farm profits (income minus costs)
Equal variances assumed 0.342 0.559 -0.165 314 0.869 -0.019 0.113 -0.241 0.204
Equal variances not assumed
-0.173 121.3 0.863 -0.019 0.108 -0.233 0.196
Minimising risk (of very high costs or very low income)
Equal variances assumed 0.905 0.342 -0.583 315 0.560 -0.078 0.133 -0.340 0.185
Equal variances not assumed
-0.612 122.2 0.542 -0.078 0.127 -0.330 0.174
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Servicing debt
Equal variances assumed 1.934 0.165 1.585 309 0.114 0.301 0.190 -0.073 0.675
Equal variances not assumed
1.575 113.5 0.118 0.301 0.191 -0.078 0.680
Having time to pursue hobbies
Equal variances assumed 0.406 0.525 -0.825 315 0.410 -0.163 0.197 -0.551 0.225
Equal variances not assumed
-0.865 122.1 0.389 -0.163 0.188 -0.535 0.210
Being able to make your own decisions about your farm/property
Equal variances assumed 0.107 0.744 0.250 315 0.803 0.026 0.104 -0.179 0.231
Equal variances not assumed
0.265 124.4 0.792 0.026 0.098 -0.169 0.221
Learning about and testing new ways of doing things on your farm/property
Equal variances assumed 0.959 0.328 0.785 315 0.433 0.091 0.116 -0.137 0.319
Equal variances not assumed
0.780 112.5 0.437 0.091 0.116 -0.140 0.322
Sharing new ideas with others
Equal variances assumed 4.303 0.039 2.122 316 0.035 0.319 0.150 0.023 0.614
Equal variances not assumed
2.005 107.1 0.047 0.319 0.159 0.004 0.634
Having efforts recognised by the wider community
Equal variances assumed 2.865 0.091 -1.924 315 0.055 -0.428 0.222 -0.865 0.010
Equal variances not assumed
-2.112 135.2 0.037 -0.428 0.203 -0.828 -0.027
Leaving the land/farm in better condition than it was when you first started managing it
Equal variances assumed 1.147 0.285 -0.611 314 0.542 -0.060 0.098 -0.254 0.134
Equal variances not assumed
-0.688 138.9 0.493 -0.060 0.087 -0.233 0.113
Maintaining/improving water supplies and storages
Equal variances assumed 0.032 0.859 0.253 276 0.800 0.060 0.236 -0.405 0.524
Equal variances not assumed
0.255 125.6 0.799 0.060 0.234 -0.404 0.524
Minimising sediment run-off and/or nutrient losses
Equal variances assumed 3.537 0.061 2.067 312 0.040 0.227 0.110 0.011 0.444
Equal variances not assumed
1.843 98.4 0.068 0.227 0.123 -0.017 0.472
Helping to safeguard native plants and animals
Equal variances assumed 3.003 0.084 1.526 312 0.128 0.224 0.147 -0.065 0.512
Equal variances not assumed
1.392 102.9 0.167 0.224 0.161 -0.095 0.542
Helping to safeguard local waterways
Equal variances assumed 0.749 0.388 2.614 313 0.009 0.309 0.118 0.076 0.541
Equal variances not assumed
2.241 95.8 0.027 0.309 0.138 0.035 0.582
Helping to safeguard the Great Barrier Reef
Equal variances assumed 0.538 0.464 2.572 313 0.011 0.326 0.127 0.076 0.575
Equal variances not assumed
2.290 99.9 0.024 0.326 0.142 0.044 0.608
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APPENDIX 3: EXAMPLES OF INNOVATIVE NUTRIENT
MANAGEMENT PRACTICES, ANECDOTAL COMMENTS
FROM WET TROPIC SUGAR CANE LAND MANAGERS,
CODED
Code Theme
1 Fertiliser/Bio Fertiliser
2 Alternative Crops/Irrigation
3 Headlands/Drains/Recycle Pits
4 Composting
5 Minimum Till
6 Stool Splitting Mixed Method
7 Best Management Practices
8 Green Trash Blanket
9 Laser Levelling
Examples of innovative practices, anecdotal comments from Wet Tropics land managers
1st Round
3rd Round
1 Adding humates/Split application of fertiliser and liquid fertiliser
1 apply mill mud/ ash subsurface under the stool at 25 tonnes a hectare
1 All fertilisers under soil 1 black urea at reduced rates of N
1 Alternate fertiliser 1 Black urea; variable rate fertiliser applications, lots of trialling
1 Bio fertiliser 1 Controlled Traffic, Nutrient Management Plans that use soil maps per block to give N recommendations.
1 Black urea 1 EEF Fertilisers on ratoons
1 Burying fertiliser 1 Enhanced efficiency fertiliser testing
1 Change to entec fertilisers 1 Mill mud, ash, I have allowed MIP to do water quality monitoring and install a bioreactor
1 Col gran to reduce volatility 1 Mix fertiliser with humid acid before applying
1 Delay fertilising, fertilise on weather 1 moved to subsurface application
1 EEF 1 place under ground
1 EEF's 1 Put a carbon souse with nitrogen
1 EEF's/Stool splitting/Zonal mill mud application/Minimum tillage
1 Slow release area
1 EFF variable rate application 1 split application and burying it
1 Entrench - help uptake/reduce loss of fertiliser
1 Split application of liquid fertiliser
1 Fertiliser at correct time, do not fertilise in wet
1 Subsurface application of fertilizers
1 Fertiliser incorporated in soil 1 Subsurface fertilizing and slow release nitrogen
1 Fertiliser is put underground; and we apply it when the weather is fine
1 Trailing a new fertiliser box attachment known as 'Stoolzippa" across a range of soil types to benchmark it's effectiveness
152
Examples of innovative practices, anecdotal comments from Wet Tropics land managers
1st Round
3rd Round
1 GPS rate control on fertiliser application 1 Trial of eek. Subsurface application, trash blanket, microbes
1 Humic acid and trace elements, trap N 1 Trialling Enhanced Efficiency Fertilisers; substituting mill mud for chemical fertiliser
1 Humic acid with Urea 1 trailing slow release fertiliser
1 I place my fertiliser under the trash in the ground beside the stool 2 row at a time 4 wheel that carry the 4 tonnes box the top where the fertiliser is put
1 trialling split application and lower rates of nitrogen
1 I put fertiliser underground will look at entech (fertiliser) in the future
1 Trying Entec, rate control on subsurface applicator, minimum tillage and controlled traffic
1 I use pelletised pouching manure as fertiliser in the cane with a N-content of 3.5% that is the best I can do
1 Use less nitrogen
1 Improving soil health by applying ash or compost
1 use mill mud a slow release fertiliser on ratoons
1 In bananas we use enhanced efficiency fertiliser and humates with our nitrogen
1 Use mill mud and bean crops to reduce the plant fertiliser rate
1 Interested in enhanced efficiency fertilising 1 Used enhanced efficiency fertilisers eg agromaster and entec
1 Irrigate in fertiliser with travelling irrigator 1 Uses Mill Ash where possibly but poor facilities at South Johnstone Mill
1 Lime regularly 1 Using biological amendments
1 Liming and mill ash - having all nutrient balanced mean less N is possible
1 Variable rate fertilizer box
1 Liquid fertiliser 2 Grow legumes crop and discounted nitrogen by not side dressing. Trial soil microbes
1 Liquid fertiliser, organic based proven to have 10% less N loss over 120 days
2 I utilise legume crops in my fallow and I account for this nitrogen in my plant crop
1 Liquid force fertiliser trace elements, organic humates and biology
2 Legume crop
1 Low nitrogen trials 2 legume planting, stool splitting, mound planting
1 Mill ash and mill mud on both areas ratoon 2 legume planting, stool splitting, mound planting, use of soil ameliorants
1 Mill ash with reduced N - but ash is very clean at $800/Ac often nice subsidy!
2 Legume planting, stool splitting, use of soil ameliorants
1 Mill mud on all ratoons/Trailing enhanced efficiency fertiliser
2 Legumes
1 Minimal or zero fertiliser in hollow areas/Spray out fallow
2 Legumes, considering using slow-release fertiliser
1 Place fertiliser underground 2 Legumes, I tried entec but did not see any economic benefit so won't be doing it again unless the price drops
1 Put fertiliser subsurface 2 reduced rates and multi species cover crops
1 Reduce fertiliser 2 wetland treating 50 ha of property run-off; legume cover crops in fallow
1 Refer to soil samples and utilise sub-surface when applying nitrogen
4 Developed an on-farm wetland; use cover crops; legume fallows (no bare fallows)
1 Side over and bury fertiliser/Used to use legume
4 Extensive wetlands > 100ha; trialling different fertilisers all the time
153
Examples of innovative practices, anecdotal comments from Wet Tropics land managers
1st Round
3rd Round
1 Slow release fertiliser (entec) or Nitro 4 Local drainage; cross-drains; a little sub-surface drainage. Molasses supplement to reduce nitrogen rates
1 Slow release fertiliser organic fertilisers 4 silt traps, variable rate and gps precision equipment, riparian zones, weather forecasting
1 Slow release fertiliser/Good fallow cover - no bare ground
5 Composting and legume fallow as revegetation of creeks and silt trapping drains
1 Sub soil stox application. Lonf size ratooning cycle
6 Zero Till planting reduced rates
1 Sub surface fertiliser/Maintain grass of headlands
6 Zonal tillage/stool split
1 Sub-surface application of fertiliser (stool splitter fertiliser box). This year also used Entec (slow release fertiliser)
7 Stool split fertiliser application
1 Subsoil application and slow release 7 Stool splitter to fertilize under ground
1 Subsurface 7 Stool Splitter, Enhanced Efficiency Fertilisers
1 Subsurface fertiliser, GCTB, mound planting, laser levelling
7 stool splitting, legume planting, use of soil ameliorants, mound planting
1 SVD surface fertiliser adp and zoal HOF 8 BMP accredited
1 Trailing entec/Calgreen below ground 8 Smartcane BMP and Composting
1 Trailing mill mud 28% reduction in bagged fertiliser in 2016
9 Trash blanket, sediment traps
1 Trialled entec, trialled liquid fertiliser - plant and ratoon
10 I have been laser levelling paddocks since the late 1990s
1 Trials with bio fertiliser, potassium
1 Trials with EEF; liquid fertiliser; Turn N; Hibrix; low herbicides
1 Tried control release fertiliser (EEF)/Variable rate fertiliser box (manage areas differently)/Would like to load at green siller
1 Urea placed under ground always
1 Use entec - 2 years trial
1 Use humate with the nitrogen application
1 Use lime/Mill mud and millash on occasion
1 Use lots of lime
1 Used entec year before last and legumes
1 Using ENTEC
1 Using high levels of mill mud
1 Using mill mud on lat cut cane for slow N release
1 Using some mill by-products
1 Variable rate controller/Legumes/Mill mud/Crop age/Harvest time
1 Variable rate fertiliser application
1 Variable rate fertiliser application and experimenting on how to use this better
1 Variable rate fertiliser application; timing of application
154
Examples of innovative practices, anecdotal comments from Wet Tropics land managers
1st Round
3rd Round
1 Variable rate fertiliser box
1 Variable rate nutrient application
1 We began applying fertiliser underground instead of top dressing in 2017
2 All our fallows are planted with legumes
2 Ash/Fallow in soybean
2 Fallow management with legumes/Entec slow-release fertiliser in 3rd pass harvest (Oct)
2 Good cover crops/Diversion drains for water control
2 Good fallow crops when possible or sprayout
2 Good fallow with soy beans to reduce N needs
2 High importance of legume fallow
2 Legume crops in fallow
2 Legume, controlled traffic, mound planting
2 Peanut/Rice legume fallow
2 Plant legume in fallow
2 Use soybean fallow to reduce N in plant; Maintain trash blanket on fallow and ratoon crops
2 Use t-tape for irrigation
4 Adjusting soil pH/Spoon draining and re-direct water away from erosion lines/More headlands
4 Are trialling Entec Urea. Changing flood irrigation system, re-jet cache pivot irrigator
4 Cleaning and re-grassing drains; slow release fertiliser
4 Developed wetland
4 Drained sub-basin
4 Grass headlands, silt traps, rock stabilisation
4 Grass seeding sediment pit
4 Grassed headlands/Vegetated drains
4 Incorporating mill mud/ash; re-cleaning soil from headlands and drains
4 Keep headland well grassed & mowed to hold sediment. All fertiliser goes underground here you can't afford to waste
4 Mounding/EEF's
4 Pastures and sediment traps, GCTB
4 Timing of application and use of drainage to dry out paddocks
5 Compost recycling/Legume fallow
5 Composting - biosilids, tree mulch
6 Fertilise at optimal time re weather and root growth - no till during wet season
6 Minimum tillage
155
Examples of innovative practices, anecdotal comments from Wet Tropics land managers
1st Round
3rd Round
6 Minimum tillage/cultivation
6 Minimum tillage/Plant with zero fertiliser
6 Minimum tillage/Reduced inorganic N application through use of mill mud/Legume fallow
6 Zero tillage/Legume fallow/Trash blanket
7 Split application with overhead irrigation
7 Split stool variable rate application for fertiliser
7 Stool spitter planting legumes
7 Stool split
7 Stool split apply fertiliser
7 Stool split, EEF's, GCTB, mound planting, legumes
7 Stool split, EEF's, mound planting, laser levelling, legumes
7 Stool split, Entec, mound planting, legumes
7 Stool split, legumes, laser levelling, mound planting
7 Stool split, mound planting, legumes, sediment trap, laser levelling
7 Stool split, mound planting, legumes, sediment traps, laser levelling
7 Stool splitting, green cane trash blanket, mound planting
7 Stool splitting - underground placement of nitrogen
7 Stool splitting ratoon cane under soil
7 Stool splitting some at the farm/Mill mud
7 Stool splitting to capture N organic fertilisers
7 Stool splitting, Aerocote - could not see any difference; Entrench - could not see any difference
7 Stool splitting; EEF - Entee
7 Stool splitting/EEF's/Mixed cropping/Mill mud
7 Stool splitting/Granular fertiliser
7 Stool splitting/Legumes/Control traffic/Uniform planting
7 Stool splitting/Low N blends
7 Stool splitting/Mill ash/Cousa crops/EE fertiliser
7 Stool splitting/Mill mud and ash/Legumes
7 Stool splitting/No till fallow/Trash blanket/6 Easy Steps
7 Stool splitting
8 BMP
9 Green cane trash blanket/All fertiliser applied sub-surface
156
Examples of innovative practices, anecdotal comments from Wet Tropics land managers
1st Round
3rd Round
9 Green trash blanket/Stool splittings for application/Spray out fallow/Legume cover crop
9 Trash blanket, never burnt trash always incorporate trash into soil for fallow and plant legumes 25 years
9 Trash blanket/Headlands
9 Trash to make earth walls in gullies and washouts
10 Laser levelling/Traffic control/New probes
10 Precision Ag
10 Laser levelling
157
APPENDIX 4: EXAMPLES OF INNOVATIVE NUTRIENT
MANAGEMENT PRACTICES, ANECDOTAL COMMENTS
FROM DRY TROPICS SUGAR CANE LAND MANAGERS,
CODED
Code Theme
1 Fertiliser/Bio Fertiliser
2 Alternative Crops/Irrigation
3 Headlands/Drains/Recycle Pits
4 Stool Splitting/Mixed Method
5 Best Management Practices
6 Applied Humates
7 Automated Flood System
8 Water/Soil Testing
Examples of innovative practices, anecdotal comments from Dry Topics land managers
1 Applying mill mud and applying fertiliser banded into the cane stool
1 Fertilizer boxes to make sure nitrogen is in the ground. put mud and ash in the ground
1 GPS rate control and placement 1 Variable rate gps controllers for fertiliser and chemical control. Capture most of my run-off except for after rain events which is time consuming
1 Slow release fertilizers 1 When we have previously grown 'organic bananas' we used a lot of natural products, chicken manure, fish scrapes. pinto peanuts.
1 The placement of fertiliser and where it gets put in the paddock - right heights so water doesn't leach it out. Minimise leaching.
2 Legume Crops
1 Waiting a specified time to irrigate after fertiliser has been applied and keeping Run-off to a minimum for the first 3 irrigations
2 Placement of nitrogen, drip irrigation, growing pulses-small increments over a long time.
2 EM Surveys and Legumes 2 Planting legumes, banded mill mud and banded sub surface mill mud applications
2 Hole fills up with overflow - council classed as sediment trap. Put crop on fallow to minimise run-off
2 Solid fertilizers I place them in the soil close to plant. Use cover crops to help stop Run-off. Useful to stop soil runaway during floods. Can make money from that cover crop. Trickle irrigation - actually used more water. Things need to be studied as a whole. Feels like more questions could have been asked.
2 Overhead irrigation, variable rate control. 3 I use end banks and grassed headlands
158
3 Trash incorporator - he wasn't sure of name. Destroy hill, cultivate fertiliser into it, rebuild hill with topsoil. Target at roots. No fertiliser in atmosphere - otherwise evaporation and waste money.
3 Series of lagoons to capture sediment Run-off
4 Double disc openers, Variable Rate controllers,
4 Placing fertilizer up on the hill & foliage spray. Stool split fertilizer.
4 Green cane harvesting, covered crops, beans, spoon drains, minimum tillage
5 Not sure what this question means i have been at best practice all my farming life and i am quick ot change as new information becomes available.
4 I use a stool splitter to fertilize my cane, 5 When we surface apply liquid fertiliser we do so in two narrow bands either side of the crest of the hill. The idea of this is the put it in the zone where it will get wet by irrigation water soaking up to it but will be high enough out of the water furrow so that irrigation water won't wash it away. We also delay irrigation for 10-15 days after fert application to reduce losses as research has shown this helps. We have been involved in various nutrient run-off initiatives over the years and are always adjusting our practices to the latest research in this area.
4 Stool split disc openers, zero tillage bi annually, end banks,
6 I apply humates with the fertiliser application to stabilize the nutrients from leaching
4 Stool splitter 7 Automated irrigation
4 Stool splitting, minimum stillage, 8 Continuous nitrogen monitor, connected to weather system. I track any leaking nitrogen in system.
5 Grant to improve farming practices
5 Integrated system where the land and water resources come before financial wealth,
I do not have nitrogen Run-off from my farms. I am very, very insulted that everyone assumes I am wrecking the reef. Pisses me off. I love the reef. Please check the science. It is wrong
6 Put fertiliser at top of hill so doesn't Run-off. Uses 'humate' carbon to help slower release fertiliser
6 We add soluble humates and soil microbes as the fertilizer is placed in the ground
7 Designing an automated system for flood irrigation
8 Water sampling/testing, soil testing, government data for bore regiments
159
APPENDIX 5: EXAMPLES OF INNOVATIVE RUN-OFF
MANAGEMENT PRACTICES, ANECDOTAL COMMENTS
FROM BURDEKIN GRAZING LAND MANAGERS,
CODED
Code Theme
1 Contouring banks
2 Erosion Prevention Project
3 Riparian Zone Management
4 Maximum Pasture Management
5 Gully Management
6 Grazing Management Practices
7 Fencing
8 Nothing, stopped by GOV regulations
Examples of innovative practices, anecdotal comments from Burdekin grazing land managers
1st Round
Blade ploughing, contour banks 1 1
Completed an erosion prevention project with NQDT 1 2
Minimise stock to help with growth, in future plant trees in bare areas, soil samples to improve soil.
1 2
Put in small deviation bank and tracks - use Darrel Hills methods - own grating system 1 2
Seeded, cleared, soil management on roars, repaired breakaway country, seeded clay pans
1 2
Try to put down sticks and regenerate species. 1 2
We do remedial work on badly eroded areas * ( These areas are from constant stocking under previous management)
1 2
Don’t burn, look after riparian areas by only grazing while there is sufficient feed, waterways are all fenced
1 3
Maximum pasture management is the best we have at the moment 1 4
The best way to reduce Run-off is by land clearing do that the grass can hold the soil 1 4
Filling gully heads with rocks/sand etc. to reduce speed of Run-off into the eroded areas 1 5
Putting logs in gullies 1 5
NO BLADES ON THE GROUND. FENCE TO CONTOUR WHERE PRACTICAL 1 6
Off stream water, fencing water ways, adjusting stocking rates. This land type doesn’t have too much run-off issues either
1 6
Will fence off areas if needed 1 6
Survey road placements and utilise contour banking - use slopes. We have a weed management practice that minimises the impact of weeds of high stock/high traffic areas. Pest eradication program e.g. Macropods, to minimise grazing pressure from non-controlled species.
1 0
Wanting to
Total 16 15
160
3rd Round
Contour ripple prevents run-off 1 1
Cutter bar - breaks the soil up, creates a good seed bed, and leaves it lumpy to capture water run-off. Retains the water and the old leaf /feed material does not get washed away, it stays on the soil. The best way to improve the soil condition.
1 2
Pondage banks 1 2
Put woo boys when making roads 1 2
Hoof Impact on scaled areas. Careful management of pastures 1 4
Just ground cover in areas prone to fast Run-off 1 4
Spraying wood weeds to encourage grass growth along waterways 1 4
No major water ways on block. We do try to reduce gully erosion by using conservative stocking rates and reduce road erosion by using well-constructed roads with diversion drains
1 5
Try and fill in whenever it erodes. 1 5
Grazing practice - two lots of breeders combined to 2 mobs, shift from one paddock to another over a period time depending on paddock size, and keeps them moving depending on the grass regrowth more regularly
1 6
Provide watering points away from waterways as there is no permanent water 1 6
Using cattle as a tool to improve the ground cover & soil structure is the only practical approach
1 6
Fence according to soil types and what is required i.e. if it's more prone to erosion. Off stream watering points
1 7
Gov regulations prevents us developing full sediment control systems. Example; invented native species numbers habitat in our area veg management laws prevent sediment run-off programs
1 8
Total 14
161
APPENDIX 6: TOP CAUSES OF POOR WATER QUALITY IN
LOCAL STREAMS, RIVERS AND WATERWAYS,
ANECDOTAL COMMENTS FROM WET TROPICS LAND
MANAGERS, CODED
Code Theme
1 Farming (Banana, Cane, Grazing and Fruit Growing)
2 Erosion
3 Bare ground
4 Blockages in creeks, cleaning creeks and drains
5 Construction/Civil Works
6 Climate Change/Global Warming
7 Cultivation Practices
8 Weather/Natural Run-off/Floods/Rainfall
9 Feral Animals (Pigs)
10 No poor water quality
11 Illegal dumping/Accidental Spills/Pollution
12 Urban Development
13 Other Industry or Government
14 Run-off
15 Don't know
162
What are the top causes of poor water quality in your local streams, rivers & waterways?
1st Round 3rd Round
Code n Code n Code n Code n
A little from cane farms - most sediments come from up-stream
1 1 5% of farmers not following proper practices
1 1 Banana growers 1 1 Agricultural run-off 1 1
Banana farm harvesting in wet weather
1 1 Badly managed fallow 1 1 chemical contamination
1 1 bam a farms
1 1
Banana farmers working ground in wet season
1 1 Banana farm run-off chemicals into waterways Aerial spraying and fertilising
1 1 Fruit growers 1 1 Banana bags 1 1
Banana farms 1 5 Banana farms 1 3 Fruit farmers sediment
1 1 Banana farmers 1 1
Bananas 1 2 Banana growers 1 2 Fruit growers causing high sediment load
1 1 chemical and sediment 1 1
Bananas, traitors fertiliser, chemicals
1 1 Bananas 1 1 N Losses 1 1 chemicals 1 1
Break down of carbon - trash blanket
1 1 Cattle farming 1 1 Nutrient 1 1 Graziers 1 1
Cane farming 1 1 Chemicals 1 1 Nutrient loss 1 1 Grazing 1 1
Cane harvesting in the wet 1 1 Erosion used in bananas 1 1 Nutrients 1 1 Leaching of nutrients into ground water
1 1
DIN 1 1 Excess nutrients from agriculture
1 1 Nutrition in water 1 1 Nutrient and herbicide run-off
1 1
Farm and bank erosion; lots of drainsin vegetation
1 1 Fertiliser & chemicals 1 1 sediment loss from Bananas
1 1 nutrient contamination 1 1
Farming practices 1 1 Fertilising on top of ground and having at run all over end of headlands
1 1 Sugar cane farming 1 1 Pesticides 1 1
Fertiliser practices 1 1 Increased nutrient loads 1 1 The few cowboys that are still out there
1 1 Poor farming methods 1 1
Fruit growers 1 1 Lack of control on timing of farm practices through external resources
1 1 Up-stream farmers 1 1 Bank Slumps 2 1
Hobby farmers 1 1 Lack of sediment traps 1 1 erosion 2 3 Erosion 2 3
Inappropriate spraying 1 1 lack of silt traps 1 1 Erosion 2 2 Erosion - sediment 2 1
Intensive livestock farming 1 1 Less opportunity for fertilising at the right time
1 1 erosion causing sediment
2 1 Soil erosion 2 1
163
What are the top causes of poor water quality in your local streams, rivers & waterways?
1st Round 3rd Round
Code n Code n Code n Code n
Lack of fallow crop 1 1 Longer season length greatly increases risk of ill-timed fertiliser application
1 1 Erosion from local roadways
2 1 Bad drainage 4 1
Lack of riparian vegetation 1 2 Nutrient losses 1 1 erosion in rivers 2 1 Local creek full of aquatic life
4 1
Late finish to harvets spraying 1 1 Nutrients flowing out of suburbs
1 1 Erosion 2 1 poor or no stream maintenance
4 1
Late harvest 1 1 Often agricultural industries are not regulated as such as cane
1 1 river bank slumping 2 1 Poorly maintained drainage systems
4 1
May be chemical 1 1 Over application of fertiliser and chemicals
1 1 riverbank erosion 2 1 waterway connectivity 4 1
Mill closures - extended cutting 1 1 Pesticides 1 1 Riverbank erosion 2 1 weeds 4 1
Nutrient loss 1 1 Poor quality riparian vegetation
1 1 Upstream erosion caused by heavy rainfall
2 1 Climate change 6 1
Nutrient; bananas 1 1 Poor riparian vegetation 1 2 Exotic weeds 4 1 Cultivation of land 7 1
Pesticide load 1 1 Rubbish - banana bags, irrigation pipe
1 1 Hymenachne grass 4 1 Poor cultivation practices 7 1
Poor farming practices 1 1 Sugar in the cane trash is a big polluter
1 1 Invasive weeds 4 1 Floods 8 2
Poor riparian management 1 1 Wildlife and landholders in the up-stream of the farming area
1 1 Plant material accumulation in waterways
4 1 Heavy floods 8 1
Poorly applied fertiliser/chemical - other farmers not me)
1 1 Banks collapsing 2 1 Stagnant waters 4 1 High flooding in wet season 8 1
Run-off from banana farms 1 2 Erosion from roads 2 1 Unstable banks on Liverpool Creek
4 1 high rainfall 8 1
Sediments/Nutrients/Chemical run-off
1 1 Erosion of creek banks 2 1 Climate change 6 1 High rainfall 8 1
Surface application of fertiliser 1 1 River bank erosion 2 1 Cultivation for cropping
7 1 High rainffall 8 1
Up-stream farming practices 1 1 Any exposed soil (e.g. pigs, roads, cow paddocks etc.)
3 1 Erosion, cultivation at inappropriate times
7 1 High volume rainfall 8 1
Upper catchment 1 1 Bare horticultural land 3 1 land mismanagement
7 1 Massive rain events 8 1
Upstream activities 1 1 Bare paddocks 3 1 Colour of local soil 8 1 Natural disasters 8 1
164
What are the top causes of poor water quality in your local streams, rivers & waterways?
1st Round 3rd Round
Code n Code n Code n Code n
Bank erosion 2 2 Due to overgrazing; lack of cover from fires and overgrazing; also heavy storms
3 1 Cyclones 8 2 Rainforest nutrients 8 1
Bank erosion from high bank 2 1 Lack of ground covers 3 1 Cyclones 8 1 Run-off from Massie rainfall events
8 1
Erosion 2 4 Poor bank stability 3 1 Excess flooding 8 1 Run-off from rainforest, woodlands, roads, drains and urban development
8 1
Erosion from all sources - feral pigs 2 1 Uncovered fallow 3 1 Extreme rainfall events
8 1 Tannins from swamp leaves: Not permitted to burn swamps so leaf litter has built considerably
8 1
In wet season bank erosion 2 1 Working your soil 3 1 Extreme weather events
8 1 Feral pigs in world heritage 9 1
Loose soil 2 1 Choked waterways 4 1 Flood 8 1 Pigs 9 2
Rangelands erosion - tablelands 2 1 Invasive weed and urban 4 1 Flooding 8 2 Pigs 9 1
River bank erosion 2 1 Lack of funding to inhibit pest weeds in waterways
4 1 Flooding 8 2 Pigs and vermin 9 1
Soil erosion 2 1 Local Council - don't maintain drains
4 1 FLOODING 8 1 Pigs digging up stream banks, paddocks
9 1
Soil loss 2 1 Poor drainage 4 1 Floods 8 2 Wallabies 9 1
Soil movement 2 1 Poor flow is vary by conditions
4 1 Heavy rainfall 8 1 Who says the water quality is poor?
10 1
Soil run-off/erosion 2 1 Poor flow path due to fallen trees
4 1 Heavy rainfall area causing soil erosion
8 1 Human encroachment 12 1
Soil types (not holding nutriens) 2 1 Sediment build up in waterways
4 1 Heavy rainfall with soil erosion
8 1 Roads poorly drained into waterway
12 1
Top soil erosion 2 1 Unable to burn swamps. All reef water makes water black
4 1 High rainfall events 8 1 Run-off from the high way 12 1
Bare fallow 3 1 Weeds 4 1 huge downpours of rain
8 1 Secondary treatment sewerage plants
12 1
Bare ground 3 1 Broken flood gate up to 3m tides
5 1 Major flood events 8 1 Urban development 12 1
Bare soil 3 1 Local Council and main roads
5 1 Major flooding 8 1 Urban encroachment 12 1
165
What are the top causes of poor water quality in your local streams, rivers & waterways?
1st Round 3rd Round
Code n Code n Code n Code n
Erosion from bare fallow 3 2 Cultivation during wet season
7 1 Run-off from upper catchment
8 1 Urban encroachment 12 1
Un-grassed headlands 3 1 Excessive cultivation 7 1 Run-off from world heritage areas
8 1 Urban run-off 12 1
Unsealed roads 3 1 Farming practices - too much tillage
7 1 The nature of the catchment: high rainfall with rapid run-off
8 1 Urban run-off 12 1
Unstable river banks 3 1 Farming systems 7 1 upper catchment Run-off
8 1 local authorities and government departments
13 1
Unsurfaced roadways - run-off 3 1 Inappropriate timing of cultivation
7 1 upper catchment run-off
8 1 Poor conservation practices 13 1
Blockages in creeks 4 1 Poor fallow management on steeper terrain
7 1 upstream erosion 8 1 sediment 14 2
Cleaning the community waterways to reduce stagnant water
4 1 Poor farm layouts: leading to ...
7 1 Very high rainfall events
8 1 I don't know 15 1
Creeks need cleaning 4 1 Poor farming practices (e.g. full tillage)
7 1 Feral pigs 9 1 Total
64
Grass infested- lack of cleaning subsidy
4 1 Poor tillage practices 7 1 Feral pigs causing sediment
9 1 a. Round of data = 3
Hymenachne 4 1 Tillage 7 1 pigs 9 4
Hymenachne clogs up drains, then floods into paddock
4 1 Timing of fallow crop planting
7 1 Pigs 9 9
Introduced water weeds and grasses
4 1 Application of herbicied around flood event
8 2 Pigs errosion 9 1
Introduced weed species 4 1 Cyclones 8 1 Sedimenet run-off from pig damamged soil
9 1
Introduced weed species and grasses
4 1 Debris-Forrest 8 1 soil and pigs 9 1
Invasive introduced weeds species and hymenachne
4 1 Extreme weather - lanslides in world heritage
8 1 soil reosion from state forests (pigs)
9 1
Lack of flow 4 1 Flooding 8 1 Don't believe there is an issue from our farm
10 1
Overfertilising and stagnent water from swamps
4 1 Heavy rain from the rainforest
8 1 don't feel there is poor water quality in local waterways
10 1
166
What are the top causes of poor water quality in your local streams, rivers & waterways?
1st Round 3rd Round
Code n Code n Code n Code n
Poor cleaning of drains and creeks 4 1 Natural run-off 8 1 Farmers water is good quality and quite drinkable
10 1
Poor drainage 4 1 natural run-off from upper catchment
8 1 I would not say that local streams have poor water quality
10 1
Removal of swamps, lack of buffers 4 1 Nutrients from rainforest 8 1 Council and tMR sending water from subdivisions
12 1
Stagnant waters coming from sugars in cane block (from harvesting), vasted product
4 1 Old forestry tracks 8 1 Roadside run-off 12 1
Streams clogged with weeds pests 4 1 Our massive wet seasons 8 1 sediment and nutrients - from towns
12 1
Weeds in channel and local creek 4 1 Run-off non-farming areas 8 1 Sewerage works 12 1
Weeds within streams and banks 4 1 Severe weather conditions 8 1 Town 12 1
Civil construction 5 1 Stream erosion by nature (cyclones)
8 1 town communities 12 1
Council roadworks 5 1 The upper Herbert catchment
8 1 town waste 12 1
Climatic events 6 1 Water from rainforest (higher volume) flowing through paddocks
8 1 Urban development 12 2
Cultivation at the wrong 7 1 Disturbance of natural parks - feral animals
9 1 Run-off 14 1
Cultivation at the wrong time 7 1 Erosion from feral animals. Some from farming activity-sediment
9 1 sediment 14 1
Cultivation at the wrong time - grower
7 1 Feral animals 9 1 Sediment Run-off 14 1
Cultivation of plant cane 7 1 Feral pig intrusion 9 1 Don't Know 15 1
Debris from national parks 8 1 Feral pigs 9 4 I don't know 15 1
Erosion from national parks 8 1 Feral pigs in rainforest 9 1 Total
103
167
What are the top causes of poor water quality in your local streams, rivers & waterways?
1st Round 3rd Round
Code n Code n Code n Code n
Flooding 8 4 Large amounts of erosion from pigs damaging creek banks
9 1 a. Round of data = 3
Floods 8 3 Pig damage 9 1
Heavy rain 8 1 Pig damage in national parks
9 1
Heavy rainfall 8 2 Pig damage in wet season 9 1
Heavy rains at time of cultivation 8 1 Pigs in national parks 9 1
High every season rainfall (stroms) after dry weather
8 1 Run-off from national parks from pig damage
9 1
High rainfall 8 1 Tilapia in the stream (once full of bana) and tilapia dig the banks
9 1
Landslides in World Heritage - nutrient run-off
8 1 Unstable banks and pigs 9 1
National park run-off 8 1 Farm - how do we know 10 1
Natural erosion from forested areas 8 1 I would like to see proof of the water quality in our local area
10 1
Natural rainforest run-off 8 1 There are more fish than when I was a kid
10 1
Natural run-off 8 1 Accidental spills 11 1
Raw forest above us 8 1 Coastal pollution 11 1
Rotting debres 8 1 Chemicals from townships 12 1
Steep forested ranges - erosion 8 1 High run-off volumes from urban development
12 1
Steep terrain 8 1 Human ache 12 1
Torrential rain 8 1 Litter from the highways 12 1
Wet weather events 8 1 Overflow from main roads highway
12 1
Excessive rainfall, feral pigs, land slips
8 1 Population growth 12 1
Extreme weather 8 3 Timing of development 12 1
168
What are the top causes of poor water quality in your local streams, rivers & waterways?
1st Round 3rd Round
Code n Code n Code n Code n
Extreme weather events 8 2 Urban development 12 9
Weather conditions 8 1 Urban development on slopes
12 1
Feral animals 9 2 Urban run-off 12 4
Feral animals in natural areas - erosion
9 1 Urban systems 12 2
Feral pig damage in national parks 9 1 Weekend warriors in 4-wheel drivers
12 1
Feral pigs 9 12 Government infrastructure construction
13 1
Feral pigs a wildlife still matter4 in rainforest (Wet Tropics)
9 1 National park neglect 13 1
Feral pigs eroding in national parks 9 1 Saltation 14 1
Feral pigs in national parks - disturbance
9 1 Sediment loss 14 1
Feral pigs in rain forest 9 1 Awaiting results of project 25
15 1
Feral pigs in world heritage 9 2 Fuel 2 weeks
1
Feral pigs in World Heritage 9 2 Total
136
Pig damage 9 4 a. Round of data = 1
Pig damage - allow greater amount of sediment of my farm
9 1
Pig damage in national parks 9 1
Pig damage in national parks & shrub
9 1
Pigs 9 1
Run-off from naturak areas - pigs 9 1
Sediment from damaged banks including pig damage
9 1
Sediment loss from rainforest and pigs
9 1
Wild pigs 9 1
169
What are the top causes of poor water quality in your local streams, rivers & waterways?
1st Round 3rd Round
Code n Code n Code n Code n
Wild pigs in rainforest 9 1
I do not beleive the waterways are of poor quality
10 1
I do not think that tha water quality is poor
10 1
I don't think we have poor water quality
10 1
I have not send samples of our run-off away to get tested
10 1
Local streams are pretty good 10 1
Need more study 10 1
No problem with the water 10 1
The weather quality is not poor 10 1
What is the evidence of poor water quality in my local stream, river?
10 1
Without individual water quality testing on
10 1
By estimation water quality is not poor. I have a healthy habbit
10 1
Increased run-off from urban development
12 1
Increased urban encroachment 12 1
Run-off farms, natural parks, urban areas
12 1
Sewage plants 12 1
The whole community 12 1
Urban development 12 3
Urban development - new subdivisions
12 1
Urban run-off 12 5
Urban use - no filters on run-off community/town use
12 1
Illigal dumping - local problem 13 1
170
What are the top causes of poor water quality in your local streams, rivers & waterways?
1st Round 3rd Round
Code n Code n Code n Code n
Water from Government land 13 1
Other industries 13 1
Government own asset (uprooted trees in river/erosion). I can't measure the quality of water leaving my farm
14 1
Run-off 14 1
Run-off from properties up-stream 14 1
Run-off into headwaters 14 1
Run-off of dust caused by any spills 14 1
Sediment 14 3
Sediment and natural matter from upper catchment
14 1
171
APPENDIX 7: TOP PRESSURES ON THE HEALTH OF THE
GREAT BARRIER REEF, ANECDOTAL COMMENTS
FROM WET TROPICS LAND MANAGERS, CODED
Code Theme
1 Farming (Banana, Cane, Grazing and Fruit Growers)
2 Erosion
3 Fishing/Shipping/Tourism
4 Blockages in creeks, cleaning creeks and drains
5 Construction/Civil Works
6 Climate Change/Global Warming
7 Cultivation Practices
8 Weather/Natural Run-off/Floods/Rainfall
9 Feral Animals (Pigs)
10 No poor water quality
11 Illegal dumping/Accidental Spills/Pollution
12 Urban Development
13 Other Industry or Government, Research
14 Run-off/Sediment
15 Acidification/CoT/Bleaching
16 Don't know
172
What are the top two pressures on the health of the Great Barrier Reef?
1st Round 3rd Round
Code n Code n Code n Code n
Chemicals 1 1 Agriculture 1 3 bananas 1 1 agriculture adjacent to reef 1 1
Fertiliser 1 1 Banana farming 1 1 Bulk Shipping 3 1 farming 1 1
Fertiliser and chemicals 1 1 Exploration of farming 1 1 Pro Fishermen 3 1 farming 1 1
Fertiliser placement on top of stool
1 1 Farming systems 1 1 snorkelling 3 1 Overfishing 3 1
Herbicides application on timing
1 1 Fertiliser and chemicals 1 1 sunscreen on tourists 3 1 overuse of asset 3 1
Horticulture farming in the district in wet weather
1 1 Fertiliser run-off 1 1 Too many people visiting the reef
3 1 Shipping 3 1
Not enough nutrients 1 1 From farming and natural parks overrun by feral pest/pigs.
1 1 tourism 3 3 sun screen 3 1
Other agriculture 1 1 Land usage practices but these are getting better and better
1 1 Tourism 3 2 tourism 3 2
Run-off from all types of farming properties, sediment loss, urban/town areas
1 1 Nutrients from agricultural use in the catchment
1 1 TOURISM - FISHING 3 1 Tourism 3 3
Sediment from agricultural use in the catchments
1 1 Some farming (e.g. cattle)
1 1 Tourism effluent disposal directly into the ocean untreated
3 1 Tourism pressure 3 1
Accelerated run-off increasing erosion
2 1 Erosion 2 1 tourist 3 1 tourism/ over population in coastal regions
3 1
Natural erosion 2 2 Top soil run-off 2 1 tourists - human waste from boats
3 1 Tourism/Aircraft fuel 3 1
Amateur fisher 3 1 The use of reef damaging sunscreen by tourists on reef.
3 1 Tourists and sunscreen 3 1 tourists 3 2
Commercial and recreational fishers and tourism
3 1 Live trout professional fishermen
3 1 Tourists- contaminating reef with sunscreen
3 1 no stream maintenance 4 1
173
What are the top two pressures on the health of the Great Barrier Reef?
1st Round 3rd Round
Code n Code n Code n Code n
International shipping ballast
3 1 Maritime traffic (pollution from container ships)
3 1 Foreign objects in waterways
4 1 Climate change 6 5
Mooring; No solid evidence that reef health is declining
3 1 Overfishing 3 1 Climate 6 2 Global warming 6 4
More ship travel 3 1 Professional fishermen 3 1 climate change 6 3 Global warming - Coral bleaching
6 1
Overfishing 3 2 Recreational fishing activities
3 1 Climate change 6 15 Rising sea temperatures 6 1
Shipping 3 2 Shipping 3 2 Climate Change 6 1 Adverse weather conditions 8 1
Tourism 3 2 Shipping movement - resuspending sediment
3 1 global waarming 6 1 cyclones 8 5
Tourism overpressure 3 2 Shipping with antifouling paints
3 1 global warming 6 1 Cyclones 8 13
Tourism pressure 3 10
Tourism overpressure 3 3 Global warming 6 4 Heavy rainfall 8 1
Tourism/Live trout fishing
3 1 Tourism pressure 3 9 Global Warming 6 2 weather events cyclones and floods
8 1
Drainage - badly managed
4 1 Tourists 3 1 global warming / coral bleaching
6 1 Weather patterns 8 1
Climate change 6 32
Urbanisation/traffic (e.g. boats)
3 1 global warning 6 1 plastic 11 1
Climate change - natural cycle
6 1 Developers 5 1 increasing water temperatures
6 1 Plastic 11 1
Climate change - natural cycles
6 1 Climate change 6 4 Pods of elevated temperature water
6 1 plastics 11 1
Climate change - rising water temperature
6 1 Climate in general 6 1 Sea temperature fluctuations
6 1 Poison 11 1
Climate change - sun and high temperature
6 1 Climatic pressure 6 1 Sea water temperature 6 1 citys 12 1
Climate change - temperature
6 2 El-nino 6 1 warming 6 2 population pressure 12 1
Climate change cycles 6 2 Global warming 6 5 Warming of ocean and water quality
6 1 General pollution 12 1
174
What are the top two pressures on the health of the Great Barrier Reef?
1st Round 3rd Round
Code n Code n Code n Code n
Climate change/Global warming
6 1 Global warming; my core is fixing CO2 to reverse global warming
6 1 Warming of water 6 1 human waste 12 1
Climatic variability 6 1 Global warming/Cities/Urban pollution
6 1 water tempurature 6 1 Increased urbanisation 12 1
Global warming 6 16
Increasing water temperature
6 5 cyclones 8 2 people 12 1
Global warming - coral bleaching
6 1 Increasing water temperature/Polluted water
6 1 Cyclones 8 6 people going there 12 1
Global warming from the other side of the world
6 1 Lack of good wet season 6 1 Extreme weather conditions
8 2 Population 12 1
Global warming/Cyclones
6 1 Rising sea temperature 6 2 intensity of wet season 8 1 Population growth along coast
12 1
Increasing temperature 6 1 Temperature rising 6 1 Natural cycles 8 1 Towns 12 1
Increasing water temperature
6 4 Water temperature 6 1 Natural disasters (cyclones)
8 1 Urban development 12 3
Ocean temperature rising
6 1 Coastal erosion from urban run-off rainforest damage
8 1 natural rainforest run-off
8 1 urban developments 12 1
Rising sea temperature 6 1 Currents moving water north
8 1 rainfall and highflow events
8 1 Urban pollution 12 1
Sea level rise 6 1 Cyclones 8 8 pig 9 1 Urban run-off 12 1
Sea surface temperature and coral bleaching
6 1 Cyclones - weather conditions
8 1 No definative data on farm effect
10 1 urbanisation 12 1
Temperature 6 1 Cyclones and natural phenomenon and global warming
8 1 Plastics 11 2 WHAT THE PEOPLE OF SYDNEY PUT INTO THE OCEAN
12 1
Water temperature 6 1 Cyclones and other natural events
8 2 High population on coast adjacent to reef
12 1 Adani 13 1
Cultivation 7 1 Diminishing natural coastal wetlands natures filtration system
8 1 human encroachment 12 1 I think researchers are chasing money by saying there is a problem
13 1
175
What are the top two pressures on the health of the Great Barrier Reef?
1st Round 3rd Round
Code n Code n Code n Code n
Cultivation at the wrong time
7 1 Extreme weather 8 1 Humans 12 1 JCU 13 1
Cyclic weather change 8 1 Extreme weather events 8 4 population 12 1 mining 13 1
Cyclones 8 16
Frequent coastal cyclones
8 1 urban development 12 4 DIN 14 1
Cyclones & weather events
8 6 Heavy raifall ever 8 1 urban sprawl 12 1 Nitrate Run-off 14 1
Cyclones and weather 8 1 Heavy rainfall, cyclones 8 1 chemicals may play a part in reef close to the coast
14 1 Nitrogen 14 1
Extreme temperature events/cyclones
8 1 Mother nature is the boss - she has her ways which cannot be controlled
8 1 DIN 14 1 Nitrogen in rainfall: 6 - 8 kg/ha/yr in Innisfil area
14 1
Extreme weather events - cyclones
8 1 Natural cycle 8 1 Fertiliser 14 1 Nutrient and sediment from land use
14 1
Extreme weather events - temperature
8 1 Natural cycle - from nature
8 1 nutrient run-off 14 2 Nutrient run-off 14 1
Lack of rainfall 8 1 Natural cycling of biota 8 1 sediment 14 4 sediment 14 1
Mother nature 8 1 Natural disasters (e.g. cyclones)
8 2 Sediment 14 2 Sediment 14 1
Natural cycle 8 1 Natural discharges in virgin land
8 1 sediment Run-off 14 1 sediment run-off from other land uses
14 1
Natural cycle - Climate change
8 2 Rivers no long have sufficient capacity - more flooding on farms
8 1 water quality from everbody
14 1 Sediment run-offs from major rivers
14 1
Natural events of a catastrophic nature
8 1 To much emphasis is put on GBR this is all natural happens
8 1 Bleaching 15 1 Coral bleaching events 15 1
Nature cycle 8 1 Tree colour and vegetation from urban swamp
8 1 coral bleaching 15 1 COTS 15 1
176
What are the top two pressures on the health of the Great Barrier Reef?
1st Round 3rd Round
Code n Code n Code n Code n
On flow form wide ocean 8 1 Water quantity entering GBR lagoon
8 1 COT and natural influences - floods and cyclones
15 1 Crown of thorns 15 4
Weather 8 1 Weather 8 1 Crown of thorns star fish
15 1 crown of thorns starfish 15 1
Weather cycles over different periods of time
8 1 Weather patterns (cyclones, storms)
8 1 I'm not a specialist so I don't know
16 1 Crown of thorns starfish 15 1
Weather patterns 8 1 Feral pigs 9 1 I'm not qualified to answer that
16 1 cycle of bleeching and will repair its self
15 1
Pig damage in shrub and instream
9 1 Feral pigs. Damage on land causing run-off. Poor management of public lands/natinal parks. No filters on urban run-off (e.g. dirt, rubbish etc.)
9 1 Total
118 Ocean Acidification 15 1
Poorly managed national parks (e.g. pig damage)
9 1 Increasing feral pigs in national parks
9 1
Sun causing bleaching 15 1
Wild pigs in national parks
9 1 Pig damage 9 1
Cities - sewage etc. dishwashing liquid
12 1 Pigs digging up national parks and creek banks
9 1
Cities and towns (sewage etc.)
12 1 Pigs in rainforest 9 1
City waste 12 1 Fukishima disater 11 1
Coastal population 12 1 Chemical waste in urban and rural areas
12 1
Development, buildings and people
12 1 City waste water 12 1
Domestic run-off in built up communities
12 1 Coastal pollution growth 12 2
General numbers of people - increase of population
12 1 Coastal urban development
12 1
177
What are the top two pressures on the health of the Great Barrier Reef?
1st Round 3rd Round
Code n Code n Code n Code n
Human impact 12 3 Development 12 1
Human impact - tourism 12 1 Domestic sewage 12 1
Humans 12 1 Dumping of sewage on reef - they all do play part in this equally. A lot of fertilisers/herbicides and pesticides do get used in suburban areas with no restrictions - they do not stay contained on the property applied to, they also end up in drains and waterways and the reef - we all put pressure on the reef
12 1
Increasing coastal pollution
12 1 Human impact 12 1
Large cities 12 1 Human population 12 1
Men-made (Farmers and others) pollutions
12 1 Human pressure 12 1
Ocean currents bringing sewrage and urban pollutions
12 1 Human pressure on reef 12 1
Over population 12 2 Humans 12 1
Population growth on the coast
12 1 Increased urbanisation 12 1
Population pressure 12 2 Increasing population density
12 1
Residential development 12 1 Over population of coast 12 2
Run-off from city & town 12 1 Overuse 12 1
Run-off from coastal towns
12 1 Pollution 12 1
178
What are the top two pressures on the health of the Great Barrier Reef?
1st Round 3rd Round
Code n Code n Code n Code n
Sewerage system 12 1 Population encrease along the coast
12 1
Urban development 12 9 Population growth along the East coast of Australia
12 1
Urban growth - cities and towns
12 1 Population pressure 12 1
Urban run-off 12 4 Rising coastal populations
12 1
Urban spread 12 1 Sewage and run-off from greater areas of housing
12 1
Urbanisation 12 3 Sewage outfall 12 1
Government regulations 13 1 Sewerage 12 1
Increased capacity to measure pollutants will show an increase on pollutant level
13 1 Urban 12 1
People - scientists giving the wrong info
13 1 Urban and rural run-off 12 1
Political agenda 13 1 Urban development 12 5
Nutrient, sediment run-off
14 1 Urban pressure 12 1
Run-off 14 2 Urban run-off 12 4
Run-off farms all areas that impact river
14 1 Urban/Touliets/Ocean ships
12 1
Run-off from rivers 14 1 Vehicle emissions, oil etc.
12 1
Sediment 14 1 Antifouling paint 13 1
Sediment - all land uses 14 1 Industrial pollution; GBR is a fairly good self maintaining system
13 1
Sediment run-off 14 1 Management with preset agendas using partial
13 1
179
What are the top two pressures on the health of the Great Barrier Reef?
1st Round 3rd Round
Code n Code n Code n Code n
truth to drive public opinion
Water quality 14 1 Narrowly defined minority focus groups
13 1
Acidification 15 1 Politicians 13 1
Agriculture and nutrient run-off; starfish
15 1 Poor modelling 13 1
Bleaching 15 1 Sporting venues and Government infrastructure
13 1
Coral bleaching 15 4 All mainland run-off 14 1
Coral bleaching - high water temperature
15 1 Chemicals 14 1
Crown-of-thorns starfish 15 2 Direct pollutions 14 1
Natural pressures (e.g. crown of thorns)
15 1 Farms, national parks, urban areas
14 1
Don't know 16 1 Minimise sediment run-off
14 1
Don't know due to lack of evidence
16 1 Nitrogen issues 14 2
Not sure 16 1 Nutrient 14 1
Nutrients 14 1
Often Pollutions 14 1
Pesticide - CONFIDOR 14 1
Rate of run-off 14 1
Run-off 14 1
Sediment 14 2
Sediment from cattle 14 1
Sediment run-off 14 4
Water quality 14 4
180
What are the top two pressures on the health of the Great Barrier Reef?
1st Round 3rd Round
Code n Code n Code n Code n
Bleaching 15 2
Bleaching from climate change
15 1
Crown-of-thorns starfish 15 1
2
Ocean acidification, cyclones
15 1
Don't know 16 1
181
APPENDIX 8: TOP CAUSES OF POOR WATER QUALITY IN
LOCAL STREAMS, RIVERS AND WATERWAYS,
ANECDOTAL COMMENTS FROM BURDEKIN LAND
MANAGERS (CANE), CODED
Code Theme
1 Farming (Banana, Cane, Grazing and Fruit Growing)
2 Run-off
3 Weather/Natural Run-off/Floods/Rainfall
4 No poor water quality/Reef Healthy
5 Weeds
6 Urban Development
8 Feral Animals (Pigs)
9 Other Industry, Shipping, Mining or Government
11 Blockages in creeks, clearing creeks and drains
12 Erosion
15 Bare ground
16 Salinity/Calcium
17 Don't know
First Round - Top Cause 1 Code n Third Round - Top Cause 1 Code n
Applied herbicides 1 1 bad fertiliser practises 1 1
cattle country 1 1 chemical run-off 1 1
Excessive chemical usage 1 1 from irrigation going directly into channels
1 1
FARMERS WHOSE RUN-OFF WATER RUNS INTO WATER WAYS
1 1 minority group of farmers use excessive use of N and chemicals
1 1
fertilizer run-off over application 1 1 Nutrient 1 1
Green cane trash 1 1 Nutrient Run-off 1 1
nitrogen 1 1 Nutrient, chemical and sediment run-off 1 1
Old school farmers who put fertiliser on right before it rains
1 1 other irrigators; Barrata system; 1 1
People using chemical in excess - poor application. They put it on and then it rains.
1 1 Poor agricultural practices-they cannot measure run-off
1 1
people who cut 'green' and don't burn, the water goes stagnant
1 1 Spraying weeds 1 1
poor ground cover management 1 1 Trash blankets 1 1
Run-off from grazing 1 1 water quality is good could always be better most run-off is inland from cane farms no farms in the burdekin run into the river all water runs away from the river
1 1
The small percentage of bad farmers with bad farming practices
1 1 black water from wetland areas-high vegetation growth
3 1
deoxygenation 2 1 Climate - rainfall interacting with land management practices
3 1
182
First Round - Top Cause 1 Code n Third Round - Top Cause 1 Code n
It from Rain events that is out of my control.
3 1 heavy rains, irrigation doesn't move much
3 1
leahing 3 1 rainfall 3 1
No rain. 3 1 run-off after rain events 3 1
Poor govt policies re water pricing systems in the Burdekin irrigation area
4 1 soil erosion from water Run-off and rain. Look at the waterways for centuries when you see the water from rivers running out to the sea they are brown this has always happened.
6 1
i dont think there is as poor quality in our creek systems that is lead to believe. i have lived hear for 48 years and have seen a lot of changes in the barratta creek from 20 years ago when you had a dead system that you could not fish out of to now where it is vibrant and fish stocks are good and clean
8 1 all local waterways are healthy 8 1
in some circumstance it improves 8 1 water quality is good, some mud but not much run-off
8 1
We have good water in this area 8 1 Run-off 12 1
Don't know. Sewage. Big floods. 11 1 Sediment 12 1
urban run-off 11 1 Sediment runnoff from inland areas 12 1
Nutrient and sediment run-off. Burdekin less so than other areas.
12 1 water waste 12 1
Run-off from local bush 12 1 100% channel water is used in my farm and the channel quality is poorer than that of river. Don't know the exact reason.
15 1
run-off from other farms 12 1 A continuous flowing channel through the farm is turned off. the difference in water levels creates fish/turtle kills
15 1
salts in water 12 1 Area prone to salt 15 1
Sediment 12 1 High calcium on some properties 15 1
Sediment run-off 12 1 naturally alkaline has to mix with salty water
15 1
turbitity 12 1 salinity 15 2
no idea 17 1 salt intrusion 15 1
Unknown 17 1 Aquatic weeds 16 1
rotting vegetation 16 1 decaying plants ie water weeds, grasses
16 1
Water weeds 16 1 Dying vegetation(overgrown weeds & grass) in wet season
16 1
weeds 16 1 Introduced fish species and introduced weeds
16 1
What is classed as Poor Water Quality? 1 Introduced weeds 16 1
Total 36 Weeds 16 1
a. Round = First Round
Weeds and grasses 16 1
NO IDEA 17 1
none 1
unable to answer 1
Total 42
a. Round = Third Round
First Round - Second Top Cause 1 Code n Third Round - Second Top Cause 1 Code n
chemical 1 1 farm run-off 1 1
183
First Round - Top Cause 1 Code n Third Round - Top Cause 1 Code n
chemicals 1 1 Inefficient Irrigation practices 1 1
nitrates in water 1 1 nutrient run-off 1 1
Nutrients 1 1 Pesticide Run-off 1 1
other farmers 1 1 Pesticide/ old chemicals 1 1
dirty water from river 3 1 lack off rain 3 1
Storms causing overflow 3 1 leaching 3 1
mining industry 4 1 Rain events 3 1
Run-off from urban and commercial areas 11 1 goverment 4 1
black water events 12 1 poor drainage 5 1
Inland properties that are sometimes poorly managed and Natural cycles of drought
12 1 Poor land managment 5 1
poor weed control 16 1 Unseasonal heavey rain on dry bare soil combined with minimal recycle pits I’ve got them but I’m in the minority.
9 1
Total 12 Sewage pumped into our oceans 'deliberately'. Our society will be judged on this ignorant practise.
11 1
a. Round = First Round
sediment Run-off from grazing and urban use
12 1
Salt on some properties 15 1
Decaying vegetation? 16 1
Weeds 16 1
unsure 17 1
Unsure 17 1
Trawlers 1
Total 20
a. Round = Third Round
184
APPENDIX 9: TOP PRESSURES ON THE HEALTH OF THE
GREAT BARRIER REEF, ANECDOTAL COMMENTS
FROM BURDEKIN LAND MANAGERS (CANE), CODED
Code Theme
1 Climate Change/Global Warming
2 Weather/Natural Run-off/Floods/Rainfall
3 Run-off
4 Fishing/Shipping/Tourism
5 Urban Development
6 Farming (Banana, Cane, grazing and Fruit Growers)
7 Acidification/CoT/Coral Bleaching
8 Feral Animals (Pigs)
9 Other Industry, Mining, Government, Research
10 No poor water quality
11 Illegal dumping/Accidental Spills/Pollution
12 Erosion
13 Cultivation Practices
14 Blockages in creeks, cleaning creeks and drains
15 Construction/Civil Works
16 Don't know
What are the top two pressures on the health of the Great Barrier Reef?
First Round - Top Pressure Code n Third Round - Top Pressure Code n
climate change 1 1 climate 1 1
Climate Change 1 1 climate change 1 1
climate change and rising temperatures
1 1 Climate change
1 2
global warming 1 2 Climate Change 1 1
sea temperatures 1 1 CLIMATE CHANGE 1 1
Water temperature 1 1 Climate change I believe 1 1
water temperatures 1 1
Climate Change, increasing sea temp and acidification, coral bleaching
1 1
Humans in general, not just farmers. Farmers just have a bigger footprint on the land.
2 1 global warming
1 2
All cities on the coast put pressure on the reef the Run-off of rain water has a high nitrogen rate and grazers land.
2 1
Global warming
1 1
urban, cities. pollution 2 1 higher temperatures 1 1
Natural changes 3 1 Rising Ocean Temperatures 1 1
Seasons - e.g. high temperatures. Natural changes. Global warming isn't real.
3 1 city sewerage discharge
2 1
185
What are the top two pressures on the health of the Great Barrier Reef?
First Round - Top Pressure Code n Third Round - Top Pressure Code n
Weather e.g. cyclones, shipping accidents, grazing and mining 3 1
Concentrated populations along the coast-heavy metals are not controlled
2 1
weather events 3 1 Urbanisation 2 1
Weather patterns 3 1
River from excessive rainfall from out west
3 1
shipping 4 1 weather cycle 3 1
fishing 4 1 over fished 4 1
tourism 4 1 Over fishing from professionals 4 1
Tourism 4 1 Tourism 4 1
Crown of thorns.
5 1
We don't manage fishing stocks correctly - fishing waters should be managed like a farm and it would be a lot better.
4 1
Thorn fish 5 1 sun bleaching 5 1
cattle country being left bare and overgrazed causing sediment run-off
6 1 farm run-off from all farms unregulated farms 6 1
existing traditional land use practices
6 1 sediment Run-off from grazing
6 1
nitrogen 6 1 There are cowboy farmers out there 6 1
Run-off from grazing and urban develpoments
7 1 Silt and rubbish after a flood
7 1
run-off from all not eastern coast not just mackay north
7 1 silt coming down rivers, urban sewerage
7 1
sediment 7 1 Turbid water 7 1
Sediment 7 1 Mining Run-off 10 1
Sediment and nutrient run-off 7 1 Politicians 10 1
Pigs in the rainforest 9 1
Continuing funding for research sector-neg & positive
10 1
Coal mines 10 1 Data accuracy and Honesty 10 1
I think it's healthy - it's still growing. 13 1 researchers trying to keep their jobs 10 1
Oil spill 14 1
All pollution sewage, plastic, soil, all chemicals through farming, and cleaning of any kind
14 1
no idea 16 1 pollution from cities 14 1
HAVE NO OPINION 1 Pollution from cities/town 14 1
Total 36 pollution from the cities 14 1
a. Round = First Round don't know 16 1 Unsure 16 2 I am not a reef scientist 1 Total 42 a. Round = Third Round
First Round - Second top pressure
Code n Third Round - Second top pressure
Code n
climate change 1 1 climate change 1 1
Climate Change 1 1 global warming 1 1
186
climate change caused by energy hungry cities
1 1 Effluent from large cities
2 1
Environmental changes 1 1
Human activity that leads to increased Run-off. either urban or agricultural.
2 1
global warming
1 1
Human impacts that affect the ability of the reef to bounce back from bleaching. Also the fact that nutrients may be causing crown of thorns outbreaks more than would otherwise occur. I'm only going on what I've heard, I'm not a scientist. Everything we do as humans affects our environment.
2 1
Global warming 1 1
Man-made activities on land and off shore
2 1
Water temperature 1 1
non-farm public and politicians who believe them
2 1
water temperature 1 1 people 2 1
Humans 2 1
Population having access to concentrated chemicals with no MSDS sheets or awareness
2 1
Run-off from cities 2 1 Untreated sewerage 2 1
Sewage from cities. 2 1
urban development ie drains from roadways
2 1
urban effluent 2 1 cyclones 3 2
Big cyclone. 3 1 Cyclones 3 1
Cyclones 3 1
after heavy rain overflow from sewerage
3 1
extreme weather events 3 1
Bag limits should be reduced and fish sizes should be reconsidered as well.
4 1
seasonal variability 3 1 Commercial fishing 4 1
Crown of thorns. 5 1 tourism 4 2
cattle farmers 6 1
natural causes-crown of thorns, cyclones
5 1
chemical 6 1 banana farmers run-off 6 1
use of hormones on cattle production
6 1 farming/natural disasters
6 1
sediment run-off 7 1 lack of monitoring skills of farmers 6 1
stream Run-off 7 1 nitrogen 6 1
Communists and Labor party because they refuse to put money towards it.
10 1 run-off form farms
7 1
mining industry 10 1 Run-off from land 7 1
ports 10 1 Sediment 7 1
cultivation of soil, application of inorganic fertiliser, herbicide/insecticide
11 1 unwanted sediments
7 1
The Ecosystem 1 erosion from upstream 8 1
Total 27 Researchers persistent pointing of the blame to 'only one cause'
10 1
a. Round = First Round Depending on who you listen to but I think the reef is doing ok
13 1
pollution 14 1
187
Pollution from cities on the coast and
rain cycles. 14 1
Population growth in adjacent areas 14 1 Unsure 16 2 Total 36 a. Round = Third Round
188
APPENDIX 10: TOP CAUSES OF POOR WATER QUALITY IN
LOCAL STREAMS, RIVERS AND WATERWAYS,
ANECDOTAL COMMENTS FROM BURDEKIN GRAZING
LAND MANAGERS, CODED
Code Theme
1 Chemicals/contamination
2 Don't Know/Other
3 Drought
4 Erosion/sediment
5 Excessive use of fire
6 Feral animals
7 Government/Legislation/Policy
8 Heavy rainfall or extreme weather
9 Lack of rain or irregular water flow
10 Main roads
11 Mining
12 No ground cover
13 No poor water quality
14 Pollution and or rubbish
15 Poor cane farming practices
16 Poor land management
17 Poor soil
18 Poor grazing practices
19 Run-off
20 Urban development
21 Vegetation/weed management
189
What are the top causes of poor water quality in your local streams, rivers & waterways?
Cause 1 1st 3rd Cause 2 1st 3rd
Anecdotal Comment Code n n Anecdotal Comment Code n n
Contamination 1 1
High nutrient levels 1 1
Lime in the water 1 1
Chemicals 1 2
Salt intrusion 2 1
We are end of the line so extensive accumulation prior to reaching us
2 1
Drought 3 1
Drought 3 1
dry weather 3 1
Lack of rain 3 1
waterways have hardly run in the last 4 years 3 1
Lack of rainfall 3 1
erosion 4 1
Low rainfall 3 1
Gully erosion that is difficult to control 4 1
erosion upstream 4 1
soil erosion 4 1
Erosion 4 1
TOO MUCH SOIL RUN-OFF 4 1
Erosion 4 2
Sediment run-off 4 1
The abolition of the Two Chain Law in the 1960s/70s. Chain is 22 yards. Protection of the banks of creeks, was abolished.
7 1
Sediment 4 2
Cyclone damage 8 1
excessive use of fire 5 1
Heavy rain prior to land revegetating 9 1
Pigs 6 1
Fast moving water 8 1
Floods 8 1
heavy rains after dry 8 1
Irregular water flow as controlled upstream 9 1
Heavy rainfall events after prolonged dry times 8 1
Lack of wet - nothing to flush the system 9 1
no clean streams 9 1
low flows 9 1
Coal mines 11 1
no rainfall to cause running water 9 1
Overgrazing of riparian zones (river and creek frontages)
16 1
lack of rain 9 2
Lack of ground cover 12 2
Unsealed Council road through my property 10 1
rubbish from recreational campers up stream 14 1
I don’t think it is an issue in this area 13 1 poor cane farming practices (kill soil, bare soil, high artificial inputs, monoculture, no grazing animal impact)
15 1
190
What are the top causes of poor water quality in your local streams, rivers & waterways?
Cause 1 1st 3rd Cause 2 1st 3rd
Anecdotal Comment Code n n Anecdotal Comment Code n n
Mining and ground cover 11 2
using fire every year 16 1
Lack of ground cover 12 1
Property managers working the country too hard
16 1
low ground cover 12 1
mono cultures - lack of ground cover - woody weed infestations - local government failing to implicit tech in road maintenance
16 1
Properties with no ground cover 12 1
poor landscape management 16 1
Don't have poor water quality 13 1
cattle eroding stream banks 16 1
good quality water in my area, dirt in system after rain
13 1
continuous grazing and the extreme patches resulting from(outside the fence again)
16 1
We are at the head of the river system - our springs etc. are of the highest water quality when they leave our property. There is no chemical run-off from our land as we don't spray our forage crops
13 1
Poor grazing management: Over-grazing of palatable plants reducing soil cover, combined with UNDER-grazing of less-palatable plants leading to moribund plants &/or too much fire.
16 1
Pollution 14 2
Invasive weeds and pests. As well as the underutilisation of regrowth control methods, including blade-ploughing.
21 1
Sodic soil 17 1
rotting vegetation 21 1
Soil 17 1
Tree and shrub cover reducing grassland body and health.
21 1
suspended clay 17 1
weeds along waterway 21 1
poor farming/grazing practices, 18 1
Ag chemicals, lack of ground cover and topsoil stability
1
1
Bank erosion from cattle and clearing 18 1
Lack of water 3
1
lack of rotation of stock 18 1
erosion 4
4
over estimating the seasonal carrying capacity(outside our boundary)
18 1
erosion of ground cover 4
1
over grazing 18 1
Erosion, cattle watering directly in water sources and over stocking
4
1
Over grazing 18 1
Seasonal influence 4
1
191
What are the top causes of poor water quality in your local streams, rivers & waterways?
Cause 1 1st 3rd Cause 2 1st 3rd
Anecdotal Comment Code n n Anecdotal Comment Code n n
Overgrazing 18 1
Seasonal Rainfall 6
1
People who over graze & road ways 18 1
Feral pigs, flooding rains - natural takes tonnes of sediment with it.
6
1
all good - except for noxious weed problem 21 1
Flying fox colonies 8
1
Rubber vine 21 1
Creek starts running dry and fills with other crap. Some flooding = some soil.
8
1
Weed infestation and rubber vine 21 1
Stagnant water 9
1
weeds from up stream 21 1
Main Roads in Townsville, should put in sediment trap on either side of the road. Increases velocity of water which creates a gully which then runs sediment into the creek. Areas with no vegetation, hardened pan, highly erodible, they're natural but we should be doing something about it.
9
1
Woody weed Infestation 21 1
Mine water release. 10
1
leaves 21 1
From topsoil being removed from areas upstream to area downstream which effects water flow - where does it all end up!
11
1
Too much remnant vegetation 21 1
Poor ground cover 12
1
Accumulating chemicals 1
1 Poor Ground Cover 12
1
sa 1
1 rubbish along roads and beaches 12
1
Don't know 2
1 Neighbours 14
1
Drought, No rain 2
3 Poor farming practices 16
1
Not in a poor way, just no water in them due to drought
3
1 Poor livestock and pasture management 16
1
They've been the way they are for as long as I can remember
3
1 old roads tracks 16
1
Dissolving soils and eroding land 3
1 Sodic soils 16
1
EROSION 4
1 Run-off 17
1
Stream bank erosion 4
1 sediment 18
1
192
What are the top causes of poor water quality in your local streams, rivers & waterways?
Cause 1 1st 3rd Cause 2 1st 3rd
Anecdotal Comment Code n n Anecdotal Comment Code n n
Erosion 4
1 Over grazing 18
1
Sediment control 4
5 overgrazing 18
1
fence lines 4
1 Overstocking 18
1
Feral animals 6
1 People upstream who have overgrazed paddocks.
18
1
Pigs, cattle erosion 6
1 Stocking rates 19
1
Extreme weather events 8
1 Residential run-off 20
1
Heavy rain on bare paddocks. 8
1 Sewage from our city’s. Overgrazing of land, bad land management
20
1
long dry spells and heavy rainfall 8
1 Accumulating weed seeds 21
1
The speed of the Run-off after big rain. 8
1 clearing with dozers to remove weeds 21
1
very dry and hard country with heavy first rains with allot of top soil Run-off
8
1 excessive vegetation growth 21
1
Lack of decent flow due to rain fall 9
1 Virgin retention areas - because there is low established ground cover
21
1
Lack of water infiltration, when water picks up speed it picks up soil particles and takes it with it. slow the water down, so it soaks in.
9
1 Weeds from neighbours 21
1
Rainfall intensity 9
1 as
don't run long enough - not permanent 9
1
36 39
Hardly any water in them, only when it rains and its fine.
9
1
Comes from stirring up stagnant water. The water clears up when it's been running for a while.
9
1
Lack of rain - Stagnation 9
1
Lack of rain 9
2
Main Roads - Every KM of road has 150ml of material, within 9 years it's lost. 2.5 tonne per lineal metre therefore 2,500 tonnes per km replaced every 5-9 years. Actively eroding
10
1
193
What are the top causes of poor water quality in your local streams, rivers & waterways?
Cause 1 1st 3rd Cause 2 1st 3rd
Anecdotal Comment Code n n Anecdotal Comment Code n n
every day. Main Roads in Townsville, should put in sediment trap on either side of the road. Increases velocity of water which creates a gully which then runs sediment into the creek.
Coal mine pit pump outs erosion on public roads caused by poor design and lack of education
11
1
Coal Mines 11
1
Mining/Industry 11
1
Native vegetation regrowth - because it minimised the ground cover
12
1
lack of ground cover (which has nothing to do with 'stocking rate'
12
1
Lack of groundcover due to thickening of regrowth timber and the inability to manage remnant vegetation.
12
1
Poor ground cover 12
2
Fine - Crystal Clear after a decent wet 13
1
Isn’t any 13
1
No poor water quality 13
1
No water quality issues to discuss 13
1
Our water is beautiful up here, runs over basalt. 70 mil gallons a day one of the springs runs.
13
1
Our water systems have good water quality and minimal sediment loss due to improved pasture
13
1
Our waterways are in good condition 13
1
Water quality here is beautiful 13
1
We are at the head of the catchment, it's pristine.
13
1
194
What are the top causes of poor water quality in your local streams, rivers & waterways?
Cause 1 1st 3rd Cause 2 1st 3rd
Anecdotal Comment Code n n Anecdotal Comment Code n n
Cane farm Run-off 15
1
Gross overstocking 16
1
Over-burning /overgrazing 16
1
overgrazing 16
1
overstocking 18
1
Overstocking 18
1
Poor land management 18
1
Shallow depth 18
1
Run-off from poorly pastured properties 18
1
Run-off from graziers, mines and farms 19
1
urban development, vehicle oil spills, 20
1
Excessive lantana growth in streams 21
1
Noxious Weeds, Over Grazing 21
1
Weed Control - Spreading of weeds from land that isn't maintained.
21
1
vegetation management 21
1
weeds 21
1
Weeds and animal pests 21
1
increasing stem density from woody weeds and vegetation
21
1
52 70
195
APPENDIX 11: TOP PRESSURES ON THE HEALTH OF THE
GREAT BARRIER REEF, ANECDOTAL COMMENTS
FROM BURDEKIN GRAZING LAND MANAGERS,
CODED
Code Theme
1 Australian Defence Force
2 Chemical Run-off
3 Land clearing/Erosion/Lack of ground cover
4 Climate Change/Global Warming
5 Coral Bleaching/Crown of Thorns
6 Don't know/Unsure
7 Government
8 Inconsistent messages/knowledge
9 Mining
10 Natural Process
11 Other farming (not cane or grazing)
12 Pests/Weeds
13 Sediment
14 Shipping/Boating Damage
15 Tourism
16 United Nations/Greens Groups
17 Urban Development/Pollution
18 Weather Events
19 Nutrient Run-off
20 Other Run-off
21 Greenies/Do gooders
22 Sustainability
23 Recreational/Commercial Fishing
24 Lack of financial support
25 Minority Land Holders
What are the top two pressures on the health of the Great Barrier Reef?
Pressure 1 1st 3rd Pressure 2 1st 3rd
Anecdotal Comment Code n n Anecdotal Comment Code n n
Contamination 1 1
High nutrient levels 1 1
Lime in the water 1 1
Chemicals 1 2
Salt intrusion 2 1
We are end of the line so extensive accumulation prior to reaching us
2 1
Drought 3 1
Drought 3 1
dry weather 3 1
Lack of rain 3 1
196
What are the top two pressures on the health of the Great Barrier Reef?
Pressure 1 1st 3rd Pressure 2 1st 3rd
Anecdotal Comment Code n n Anecdotal Comment Code n n
waterways have hardly run in the last 4 years
3 1
Lack of rainfall 3 1
erosion 4 1
Low rainfall 3 1
Gully erosion that is difficult to control
4 1
erosion upstream 4 1
soil erosion 4 1
Erosion 4 1
TOO MUCH SOIL RUN-OFF 4 1
Erosion 4 2
Sediment run-off 4 1
The abolition of the Two Chain Law in the 1960s/70s. Chain is 22 yards. Protection of the banks of creeks, was abolished.
7 1
Sediment 4 2
Cyclone damage 8 1
excessive use of fire 5 1
Heavy rain prior to land revegetating
9 1
Pigs 6 1
Fast moving water 8 1
Floods 8 1
heavy rains after dry 8 1
Irregular water flow as controlled upstream
9 1
Heavy rainfall events after prolonged dry times
8 1
Lack of wet - nothing to flush the system
9 1
no clean streams 9 1
low flows 9 1
Coal mines 11 1
no rainfall to cause running water
9 1
Overgrazing of riparian zones (river and creek frontages)
16 1
lack of rain 9 2
Lack of ground cover 12 2
Unsealed Council road through my property
10 1
rubbish from recreational campers up stream
14 1
I don’t think it is an issue in this area
13 1 poor cane farming practices (kill soil, bare soil, high artificial inputs, monoculture, no grazing animal impact)
15 1
Mining and ground cover 11 2
using fire every year 16 1
Lack of ground cover 12 1
Property managers working the country too hard
16 1
low ground cover 12 1
mono cultures - lack of ground cover - woody weed infestations - local government failing to implicit tech in road maintenance
16 1
Properties with no ground cover
12 1
poor landscape management
16 1
Don't have poor water quality 13 1
cattle eroding stream banks
16 1
good quality water in my area, dirt in system after rain
13 1
continuous grazing and the extreme patches resulting from(outside the fence again)
16 1
197
What are the top two pressures on the health of the Great Barrier Reef?
Pressure 1 1st 3rd Pressure 2 1st 3rd
Anecdotal Comment Code n n Anecdotal Comment Code n n
We are at the head of the river system - our springs etc. are of the highest water quality when they leave our property. There is no chemical run-off from our land as we don't spray our forage crops
13 1
Poor grazing management: Over-grazing of palatable plants reducing soil cover, combined with UNDER-grazing of less-palatable plants leading to moribund plants &/or too much fire.
16 1
Pollution 14 2
Invasive weeds and pests. As well as the underutilisation of regrowth control methods, including blade-ploughing.
21 1
Sodic soil 17 1
rotting vegetation 21 1
Soil 17 1
Tree and shrub cover reducing grassland body and health.
21 1
suspended clay 17 1
weeds along waterway 21 1
poor farming/grazing practices,
18 1
Ag chemicals, lack of ground cover and topsoil stability
1
1
Bank erosion from cattle and clearing
18 1
Lack of water 3
1
lack of rotation of stock 18 1
erosion 4
4
over estimating the seasonal carrying capacity(outside our boundary)
18 1
erosion of ground cover 4
1
over grazing 18 1
Erosion, cattle watering directly in water sources and over stocking
4
1
Over grazing 18 1
Seasonal influence 4
1
Overgrazing 18 1
Seasonal Rainfall 6
1
People who over graze & road ways
18 1
Feral pigs, flooding rains - natural takes tonnes of sediment with it.
6
1
all good - except for noxious weed problem
21 1
Flying fox colonies 8
1
Rubber vine 21 1
Creek starts running dry and fills with other crap. Some flooding = some soil.
8
1
Weed infestation and rubber vine
21 1
Stagnant water 9
1
chemical Run-off from urban development 2 1 ADF 1 1 CHEMICAL, FERTILIZER, HUMAN 2 1
Chemical run-off. urban, mining and ag 2 1
Chemicals 2 1
Chemicals Run-off from town water 2 1
Chemicals - crops 2 1
Land clearing, road grading, mixed agriculture, cane farming 3 1
198
What are the top two pressures on the health of the Great Barrier Reef?
Pressure 1 1st 3rd Pressure 2 1st 3rd
Anecdotal Comment Code n n Anecdotal Comment Code n n
chemicals - pharmaceuticals/artificially manufactures substances, 2 1 Climate 4 1 Chemicals in everyday items used in the towns whose waste water goes to the reef. Cosmetics, fertilizers for gardens etc 2 1 climate change 4 2
Na 2 1 Climate change 4 1
Phosphates 2 1 Climate change, cyclones 4 1 Round up and poisons sprayed by councils to clear drains 2 1
Extremely hot temperatures (bleaching) 4 1
Water quality from chemical and topsoil run-off 2 1 Rising sea temperatures 4 1
climate change 4 1 Rising sea temps 4 1
Climate change 4 2 Sea temperature 4 1
global warming 4 1
Coral Bleaching (but I'm getting off the media which is probably not right anyway) 5 1
ocean temperatures 4 1 Crown of thorns star fish 5 1
Rising temperature 4 1
Own environmental issues i.e. crown of thorns starfish we know that there are lots of factors but none are concrete. We don't know that fertiliser or sediment are the only cause. 5 1
Sea temperature effects on coral bleaching 4 1 Don't know 6 1
Sea temperature increase 4 1 I don't know 6 1
temperature 4 1 I don’t know 6 1
Crown of thorns 5 1 Not sure - Not a scientist. 6 1 nature- crown of thorns, cyclones 5 1
Not sure maybe mining or cropping 6 1
Don't know 6 1
STILL MAKING MY OPINION 6 1
Unsure/ not qualified to answer 6 1 lack of education 8 1
which one do we believe 6 1 Coal Dust 9 1 Government parties and there opinion towards rural industry 7 1 coal ships - oil spills 9 1 A lot of the information is an inconsistent load of rubbish 8 1 Mining 9 1
lack of knowledge 8 1
Natural process of growth and decline 10 1
Grazing & agriculture (clearing) 3 1 Seasons 10 1
Mining 9 1
Large Dam on the river stopping the silt and 13 1
199
What are the top two pressures on the health of the Great Barrier Reef?
Pressure 1 1st 3rd Pressure 2 1st 3rd
Anecdotal Comment Code n n Anecdotal Comment Code n n
sediment feeding the GBR
natural growth and decline 10 1
Led to believe that it is sediment - I would imagine that the sediment that enters the reef would have some impact but the sediment would benefit in the long run. I wonder how the reef can survive nutrient wise if it didn't have the rivers to feed it 13 1
nature 10 1 Sediment 13 4
Seasonal changes 10 1
Sediment from farming and urban areas 13 1
Coastal horticulture 11 1 Sediment Run-off 13 2 I have doubts that there is an issue with the GBR, resources are being wasted here rather than looking into major environmental issues on land such as pests and weeds. 12 1 sediment run-off 13 1
Sediment 13 1 Shipping 14 1
Sediment run-off 13 1 Pollution - Rubbish 17 1
Sediment/Run-off 13 1
Cities by the coast-high population areas-high nitrogen level discharge from urban areas into ocean. 17 1
siltation 13 1 city and town pollution 17 1
Soil run-off 13 1 Coastal development 17 1
anchor damage 14 1
Human Impact - High density population and urban development 17 1
tourism 15 1
Humans - Coastal Development 17 1
Tourism 15 1
Pollution around towns and cities e.g. The excess of herbicides/insecticides/detergents to control grasses around waterways (I have seen this MANY times) etc. This would be easy to assess with monitoring stations both up AND downstream of cities and towns along river systems. The monitoring of the TYPE of sediment would also indicate where the sediment had 17 1
200
What are the top two pressures on the health of the Great Barrier Reef?
Pressure 1 1st 3rd Pressure 2 1st 3rd
Anecdotal Comment Code n n Anecdotal Comment Code n n
originated from e.g. Overland flow OR soil types from much deeper sources e.g. Mine pits.
United Nations and green groups 16 1
Pollution from the cities and towns situated along the coast, especially from sewage treatment plants 17 1
Pollution 17 1
Residential rubbish, vehicles, tyres, rubbish on beaches, changed waterways in the towns how they hit the ocean, sediment control etc. 17 1
Coastal communities who are not subject to the rules and regulations regarding domestic chemicals 17 1 Residential/city dwellers 17 1 population cities along the coast 17 1 run-off from urban areas 17 1
Rubbish from cities 17 1 Urban development 17 1 Run-off from Cities, hobby farms, backyards, crop farms & industrial activities closer to the shore. 17 1
Urban development / sewerage 17 1
Run-off of chemicals from cities and towns close to the reef 17 1 Urban Impact 17 1
Towns 17 1 urban pollution 17 1
Urban pollution and Run-off 17 1 Urban Run-off 17 1
Cyclones 18 2 Caused by cyclones 18 1
agriculture chemicals 2 1 Cyclone damage 18 1
Fertilizer/chemicals 2 1
heavy rains when allot of top soil runs down the rivers out to sea 18 1
Na 2 1 Impacts from cyclones 18 1 Some farming chemicals (Growers) Grazing has the buck passed on to them as they are an easy target 2 1
Natural Disasters (i.e. cyclones and large floods creating plumes) 18 1
Climate Change 4 1 Unpredictable Weather 18 1 Climate change, of which poor grazing land management is one of many causes. 4 1
Soil run-off, from rural, government and resource sector 20 1
climate variability 4 1 Water quality 20 1 Coastal development. and sewerage water from urban areas, Inc. Townsville Mackay Yeppoon 4 1 Green groups 21 1
Global warming 4 1 Greenies, it’s been like that for centuries 21 1
global warming 4 1 Sustainability 22 1
201
What are the top two pressures on the health of the Great Barrier Reef?
Pressure 1 1st 3rd Pressure 2 1st 3rd
Anecdotal Comment Code n n Anecdotal Comment Code n n
Crown of thorns 5 1 Closed fishing areas 23 1 We are told run-off??? Not sure 6 1
fishing (commercial and recreational) 23 1
Who does know? 6 1 illegal over fishing 23 1 Unsure/ not qualified to answer 6 1 Outboard fuel vapours 23 1
Bureaucrat 7 1 afd 1 1
Government and bureaucrats 7 1 Chemical residue 2 1
Ignorant politicians who have absolutely no idea on how the sustainable grazing industry works and haven't got the guts to monitor "big industries" such as mining industries. Easier to pick on the graziers as they don't have the money to fight them and their idiotic policies.
7
1 Chemical Run-off 2
1
Negative media coverage based on misleading percentages
8
1 Chemical run-off ; rural, urban and resource sector
2
1
contaminated water from mine sites
9
1 chemical usage in home gardens
2
1
Mining (graziers are being blamed for sediment run-off which has happened for years).
9
1 Chemical waste and plastic pollution
2
1
Mining, more unrestrained than grazing, less restrictions
9
1 Chemicals 2
2
Natural changes/cycle 10
1 Chemicals in cane farming, Urban Development,
2
1
naturally occurring events 10
1 Chemicals? 2
1
Nature - cyclones 10
1 Closely settled country close to coast little hobby farms, Run-off from those chemicals
2
1
Nutrient run-off 19
2 Led to believe that it is chemical
2
1
Farmers near the coast - NOT CATTLE GRAZIERS IN CW QLD
11
1 Topsoil instability and erosion
3
1
unclean water 20
1 Ground cover 3
1
Increased boats and decline in marine life
23
1 Increasing temperatures 4
1
over fishing 23
1 Temperature of the water 4
1
Sediment and nutrient from floods
13
1 Natural bleaching 5
1
sediment and nutrient run-off 13
1 Mining 9
2
Sediment run-off 13
1 Mining / Farming 9
1
Sediment/nutrient 13
1 Mining and dredging 9
1
202
What are the top two pressures on the health of the Great Barrier Reef?
Pressure 1 1st 3rd Pressure 2 1st 3rd
Anecdotal Comment Code n n Anecdotal Comment Code n n
Topsoil/sediment from poor farming practices
13
1 Poor mining practices 9
1
tourism 15
1 Scientists with half arse theories who don’t know shit from clay
8
1
Large Cities 17
1 environmental changes 10
1
People in the large cities 17
1 Natural Causes 10
1
people pollution 17
1 Natural degradation, tourism
10
1
pollution running off from city streets
17
1 natural disasters 10
1
urban development and pollution
17
1 Not too sure how much pressure is really on. Sometimes we get a bit neurotic about what's going on. Nature is what happens in one big cycle. In terms of geological time I think it's probably fine. We're talking about things that are happening.
10
1
Cyclone damage 18
1 Farming plays a role 11
1
cyclones and recreational fishing
18
1 Pollution, farming - but nothing has been proven
11
1
extreme weather events 18
1 Because there is no sediment the uv rays bleach the coral
13
1
flooded mine sites, large developments and dredging, chemicals
18
1 Sediment and nutrient run-off
13
1
sediment run-off from agricultural land
13
1
sediment run-off 13
1
Shipping pollution 14
1
Tourist boats / sewerage/ anchor damage
14
1
tourism 15
1
tourists - leaving rubbish 15
1
City effluents 17
1
City pollutions 17
1
General waste from town and cities. Urban gardeners using pesticides with no training or regulations.
17
1
Human Impact in general 17
1
Nutrient run-off from city & farms
17
1
pollution from urban drains
17
1
pollution run-off from urban areas
17
1
203
What are the top two pressures on the health of the Great Barrier Reef?
Pressure 1 1st 3rd Pressure 2 1st 3rd
Anecdotal Comment Code n n Anecdotal Comment Code n n
Population and coastal development
17
1
towns (lawn Fert, chem, washing powder, cleaning products, pesticides, manufacturing, rubbish dumps, fuel, oil, rubber of roads, tourists boats snorkelling rubbish,
17
1
Urban areas don't have anywhere near the restrictions that farmers do in regards to what they're allowed to use on their gardens and roads and they get more rain and flooding. Impact from urbanisation more than anything.
17
1
Urban consumers 17
1
Urban development, mining activity, creek diversions, loss of vegetation and water infiltrations, increased run-off because of loss of mature vegetation deep rooted tree
17
1
Urban Expansion 17
1
Nutrient rich water 19
1
Run-off 20
1
Run-off from interior areas
20
1
Do Gooders 21
1
Recreational fishing 23
1
Lack of financial support for improvements
24
1
Landholders who are yet to adopt best management practices. As in most cases, the minority are creating a negative stereotype despite the good work of the majority.
25
1
204
APPENDIX 12: FEEDBACK FROM LAND MANAGER
SURVEY, IMPACT OF URBAN DEVELOPMENT ON
WATER QUALITY
On 13/03/2018 12:44 PM, Participant Surname, Name supplied wrote:
Thanks for organising this survey.
Our question is, what are NQ Dry Tropics and JCU doing to assess and control the impact of
townspeople on the Great Barrier Reef? Fertilisers are allowed to be applied without restriction
to town blocks, which then run directly onto the Reef. The recent rain in Townsville washed
the dust, filth and rubber from roads into the Reef. Sewerage pours in each day, and if organic
farmers are unable to use treated sewerage water on their crops, why is it allowed to touch the
Reef? Every time the Army bombs at High Range, the creeks and rivers run brown - yet they
are allowed to continue unchecked. Developers can rip up and damage in Townsville and
where does the Run-off go? Have a look at the construction of the new stadium and the fact
it is beside the Ross River.
Your survey needs broadening.
We are tired of landholders being targeted when those who sit on the doorstep of the reef are
left alone. When are they going to be put under the microscope instead of targeting us? Those
who sit on the very edge of the Reef are impacting it most.
Thankyou,
Participant Name Surname Supplied
On 13/03/2018 6:55 PM, Researcher wrote:
Hi Participant Name,
Thank you for the feedback. I recognise and acknowledge your frustration. For this study we
are focussed on cane growers and graziers and their views on issues surrounding water quality
(and trying to keep our very long survey as short as possible). Our goal is to find out your
views so as to recognise your efforts (as landholders) towards improving water quality. We
hope to be able to use the results to compare to other study’s to highlight the importance of
improving run-off to the reef from all users, but in particular to recognise the efforts that farmers
go to, to manage run-off.
Thank you for taking the time to complete the survey, we appreciate your involvement.
Researcher name supplied
205
On 14/03/2018 9:33 AM, Participant wrote:
Hi Researcher,
Thanks for your reply. Perhaps in your position, you could start the movement to advertise
that every time a toilet is flushed or a tap is turned in a city, it impacts the reef. Media would
have us believe it is all the farmers fault and it's about time this opinion was changed by directly
challenging it.
Thankyou,
Participant
On 18/03/2018 8:44 AM, Researcher wrote:
Hi,
I think they are realising that they shouldn’t point the finger at one party, because they know
that WQ effects and is effected by everyone. In the past farming processes have been
identified as high risk for run-off from nitrogen, pesticides and sediment, hence they see
actioning farmers as important to reducing run-off. There is now acknowledgement that
focussing on a single segment/industry may not be the way to go. The government is
perplexed as to why when there is best management practice (bmp), that it is not being
adopted. We suspect that most farmers are using bmp and we know that nearly all (there’s
always exceptions) farmers care deeply for their land. Hence the reason for the survey… we
are trying to find out what farmers are doing in terms of bmp, and what they are doing differently
to standard practice (and if it’s working) and where processes/information can be changed to
‘hear the farmers voice’.
The first round of literature review has shown that communication (or lack of it) has played a
major role in poor relationships between government and land holders (again not always, but
in many cases). But the data also showed that more than 60% of farmers did not think that
their farming practices effected the reef… so we need to hear more about what land managers
are doing 3 years later to see if anything has changed.
And that’s where you come in… thanks for taking the survey… we are certainly working
towards a more balanced view
Researcher
On 19/03/2018 8:39 AM, Participant wrote:
Isn't it interesting (and scary) that it has taken this long for common sense to prevail? I think
farmer bashing is a popular sport and politicians get most votes from towns, so despite the fact
that we feed them, they would like to think we are the enemy and don't count. This is why bmp
isn't adopted, because no one wants to be on the government radar and be
206
persecuted. Farmers are the original conservationists. We care for and nurture our land to
the detriment of our own health and relationships and are sick of those with no common sense
coming out of a yearlong degree to lecture us.
What should happen, is that each farmer's knowledge and expertise of managing and
preserving their land should be celebrated and shared without feeling that big brother is waiting
to swoop.
If a greater focus was placed on townspeople, developers, the army and mining impact on the
reef, farmers would feel less persecuted and would share their already effective
practices. Most don't need to change their practices, as they aren't the sole reason for reef
impact, the above groups need to be targeted (which would cost votes, hence the reason they
never are, sadly).
Thanks again,
Participant
207
APPENDIX 13: PROJECT OUTPUTS
Technical Reports Published
Eagle, L., Hay, R., Farr, M. (2016) Harnessing the science of social marketing and behaviour
change for improved water quality in the GBR: Background review of literature. Report to the
National Environmental Science Programme. Reef and Rainforest Research Centre Limited,
Cairns (98 pp.).
Hay, R., and Eagle, L., (2016) Harnessing the science of social marketing and behaviour
change for improved water quality in the Great Barrier Reef: A documentary analysis of Reef
Trust Tender (Burdekin) and Reef Programme. Report to the National Environmental Science
Programme. Reef and Rainforest Research Centre Limited, Cairns (95 pp.).
Farr, M., Eagle, L. Hay, R., and Churchill, M. (2017) Questionnaire Design, Sampling Strategy
and Preliminary Findings: The Wet Tropics region. NESP Project 2.1.3 Interim report. Report
to the National Environmental Science Program. Reef and Rainforest Research Centre
Limited, Cairns (100pp.).
Farr, M., Eagle, L. Hay, R., and Churchill, M. (2017) Questionnaire Design, Sampling Strategy
and Preliminary Findings: The Burdekin region. NESP Project 2.1.3 Interim report. Report to
the National Environmental Science Program. Reef and Rainforest Research Centre Limited,
Cairns (124pp.).
Farr, M., Eagle, L., and Hay, R. (2017) Questionnaire Design, Sampling Strategy and
Preliminary Findings: A Comparison of the Burdekin and Wet Tropics regions. NESP Project
2.1.3 Interim report. Report to the National Environmental Science Program. Reef and
Rainforest Research Centre Limited, Cairns (70pp.).
Farr, M., Eagle, L., Hay, R. (2017). Supplementary Literature Review: Key determinants of pro-
environmental behaviour of land managers in the agricultural sector for NESP Project 2.1.3.
Harnessing the Science of social marketing and behaviour change for improved water quality
in the GBR. Report prepared for the Australian Government - National Environmental Science
Project.
Hay, R., & Eagle, L., (2018) Harnessing the science of social marketing and behaviour change
for improved water quality in the Great Barrier Reef: Land Managers decision making about
water quality: views from extension officers of the Wet Tropics, Queensland, Australia. NESP
Project 2.1.3 Interim report. Report to the National Environmental Science Programme. Reef
and Rainforest Research Centre Limited, Cairns.
The following guide has been published for associated NESP TWQ Hub Project 3.1.3
Hay, R., Eagle, L., & Chan, J. (2018). Harnessing the science of social marketing in
communication materials development and behaviour change for improved water quality in the
GBR: Best Practice GUIDE for Development and Modification of Programme Communication
Material. Retrieved from http://www.nesptropical.edu.au
208
Refereed Journal Articles
Rundle-Thiele, S.R., David, P., Willmott, T., Pang, B., Eagle, L., Hay, R. (2019). Delivering
behavioural change: A theoretical research agenda, Journal of Marketing Management, 35
(1-2), 160-181.
Hay, R., Eagle, L., Saleem, M., (2019). Social marketing’s role in improving water quality on
the Great Barrier Reef. Asia Pacific Journal of Marketing and Logistics.
Eagle, L., Hay, R. & Low, D. (2018) Competing and Conflicting Messages via Online Media:
Potential impacts of claims that the Great Barrier Reef is Dying Ocean and Coastal
Management, 158, 154-163.
Webinars
Eagle, L., Farr, M., and Hay, R. (2016) NESP Project 2.1.3: Progress update for harnessing
the science of social marketing and behaviour change for improved water quality in the GBR:
an action research project. In: Office of the Great Barrier Reef Webinar Series, pp. 1-31. From:
Office of the Great Barrier Reef Webinar Series, 10 April 2016, Brisbane, QLD, Australia.
Eagle, L. (2016). Summary of Literature Review undertaken for Harnessing the science of
social marketing and behaviour change for improved water quality in the GBR: an action
research project. In: Office of the Great Barrier Reef Webinar Series, pp. 1-31. From: Office of
the Great Barrier Reef Webinar Series, October 25 2018, Brisbane, QLD, Australia.
Hay, R., Eagle, L. & Farr, M. (2016). NESP Project 2.1.3: Harnessing the science of social
marketing and behaviour change for improved water quality in the GBR: Documentary
Analysis. In: Office of the Great Barrier Reef Webinar Series, pp. 1-31. From: Office of the
Great Barrier Reef Webinar Series, 2 November 2018, Brisbane, QLD, Australia.
Emtage, N. (2017) NESP Identifying and profiling landholder groups for social marketing: a
Wet Tropics Study. In: Office of the Great Barrier Reef Webinar Series, pp. 1-31. From: Office
of the Great Barrier Reef Webinar Series, 31 January 2017, Brisbane, QLD, Australia.
Keynote Presentations
Eagle, L. (2018). Keynote Speaker, Environmental Behaviour Change: Benefits, barriers and
the need for integrated strategies. Presented to the Estuarine and Coastal Sciences
Association Conference (ECSA57): Perth 3 – 6 September 2018
Hay, R. (2018). Keynote Speaker: Marketing communication and effectiveness. Presented to
the Regional NRM Communication and Engagement Officers Network, Terrain NRM, Cairns,
2 August 2018
Paper Presented at Refereed International Practitioner Conference
Hay, R., Eagle, L. & Farr, M. (2017). “Supporting and Extending the Role of Agricultural
Extension Officers”. Presented at the International Conference of the Australasia-Pacific
Extension Network, September. Abstract appeared in conference proceedings.
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Paper Presented at Refereed International Academic Conference
Hay, R., Eagle, L. & Low D.R. (2017). “Farmer segmentation and the transfer of knowledge in
extension”. In proceedings of the Australia New Zealand Marketing Academy Conference
(ANZMAC), RMIT Melbourne, December.
Papers under Development and Review
Under development
Rundle-Thiele, S. Pang, B., David, P., Wilmott, T., Eagle, L. & Hay, R. Synthesis of NMSC
and CBSM benchmarks – Target journal. Journal of Social Marketing
Eagle, L., Hay, R., Kubacki, K., & Rundle-Thiele, S. Social marketing will be used to
“overcome” opposition: Really? Target journal: Journal of MacroMarketing
Eagle, L., Hay, R., Rundle-Thiele, S., & Roemer, C. Engaging with the Disengaged: A
Collaborative Partnership Approach to Agricultural Land Practice. Target Journal:
Environmental Science & Policy.
Eagle, L., & Hay, R. Supporting and Extending the Role of Agricultural Extension Officers.
Target journal: Journal of Agricultural Education and Extension
Hay, R., & Eagle, L. Farmers typology and its importance for successful extension programs –
North Queensland (Australia) study. Target journal: Land use policy
Eagle, L. & Hay, R. “Gloom and Doom versus Hope for Recovery: Changing Tone in Media
Coverage of the Great Barrier Reef”. Target Journal: Communication Research.
Presentations to Industry Bodies
Hay, R., Eagle, L. & Farr, M. (2016). Project Overview for Harnessing the science of social
marketing and behaviour change for improved water quality in the GBR: an action research
project. Presentation to Successful Projects Sharing Day: Working together to improve water
quality group. Hosted Department of Environment and Heritage Protection, 15 April 2016.
Eagle, L., Hay, R. & Farr, M. (2016). Project Overview for Harnessing the science of social
marketing and behaviour change for improved water quality in the GBR: an action research
project. Presentation to NQ Dry Tropics Staff, 18 October, 2016.
Eagle, L., Hay, R. & Farr, M. (2016). Project Overview for Harnessing the science of social
marketing and behaviour change for improved water quality in the GBR: an action research
project. Presentation to Terrain Staff, 14 December 2016.
Eagle, L., Hay, R. & Farr, M. (2017). Wet Tropics Sugar Industry Partnership Management
Committee Presentation re first round of data from NESP project, April 3, 2017.
Eagle, L., Hay, R. (2017) Social Dimensions Workshop coordinated by Department of
Environment and Heritage Protection. Presentation to delegates, Brisbane, 31 January 2017.
www.nesptropical.edu.au